Compositions and methods for labeling of agents

ABSTRACT

The invention provides, inter alia, methods for uniquely labeling populations of agents of interest using random combinations of oligonucleotides. The oligonucleotides may comprise a unique nucleotide sequence and/or one or more non-nucleic acid detectable moieties.

RELATED APPLICATIONS AND INCORPORATION BY REFERENCE

This application is a continuation-in-part application of international patent application Serial No. PCT/US2013/061189 filed Sep. 23, 2013, which published as PCT Publication No. WO 2014/047561 on Mar. 27, 2014, which claims the benefit of and priority to U.S. Provisional Application Ser. No. 61/779,999, filed Mar. 13, 2013; 61/731,021, filed Nov. 29, 2012; and 61/703,884, filed Sep. 21, 2012. This application is related to U.S. Provisional Application Serial No. 61/779,999, filed March 13, 2013.

The foregoing application, and all documents cited therein (“appln cited documents”) and all documents cited or referenced in the appln cited documents, and all documents cited or referenced herein (“herein cited documents”), and all documents cited or referenced in herein cited documents, together with any manufacturer's instructions, descriptions, product specifications, and product sheets for any products mentioned herein or in any document incorporated by reference herein, are hereby incorporated herein by reference, and may be employed in the practice of the invention. More specifically, all referenced documents are incorporated by reference to the same extent as if each individual document was specifically and individually indicated to be incorporated by reference.

SEQUENCE LISTING

The instant application contains a Sequence Listing which has been submitted electronically in ASCII format and is hereby incorporated by reference in its entirety. Said ASCII copy, created on Apr. 29, 2015, is named 46783.01.2017_SL.txt and is 608,167 bytes in size.

FIELD OF THE INVENTION

The invention is directed to methods for labeling populations of agents of interest using random combinations of oligonucleotides. All documents cited to or relied upon below are expressly incorporated by reference herein.

BACKGROUND OF INVENTION

The ability to label and distinguish agents of interest (e.g., DNA, proteins, chemicals, cells, etc.) serves multiple purposes in research and industry. However, several limitations exist in current labeling technologies. These limitations include the limited number of distinguishable detectable moieties currently in existence, the amount of time required to uniquely label a plurality of agents, the requirement, in some instances, for specialized equipment, and the cost involved.

SUMMARY OF INVENTION

The invention provides, in part, methods for uniquely labeling agents in a dynamic manner. The methods allow a plurality of agents, ranging from 2 to millions of agents, to be uniquely labeled without the need to manually generate the same number of unique labels. The agents may be of diverse nature, In some important embodiments, the agents are nucleic acids such as genomic DNA fragments. The invention contemplates that agents may be labeled in order to identify them, identify their source, identify their relationship to other agents, and/or identify one or more conditions to which the agents have been subject.

The methods of the invention also provide for amplifying nucleic acids to increase the number of read pairs properly mated via their unique index combination. In a further embodiment, the method of the invention allows for each end-labeled nucleic acid to be identically labeled at its 5′ and 3′ ends.

The unique labels provided herein are at least partly nucleic acid in nature. The invention contemplates that the labels are prepared by sequentially attaching randomly selected oligonucleotides (referred to interchangeably as oligonucleotide tags) to each other. The order in which the oligonucleotides attach to each other is random and in this way the resultant label is unique from other labels so generated. The invention is based, in part, on the appreciation by the inventors that a limited number of oligonucleotides can be used to generate a much larger number of unique labels. The invention therefore allows a large number of labels to be generated (and thus a large number of agents to be uniquely labeled) using a relatively small number of oligonucleotides.

BRIEF DESCRIPTION OF DRAWINGS

Non-limiting embodiments of the present invention will be described by way of example with reference to the accompanying Figures, which are schematic and are not intended to be drawn to scale. For purposes of clarity, not every component is labeled in every figure, nor is every component of each embodiment of the invention shown where illustration is not necessary to allow those of ordinary skill in the art to understand the invention.

FIG. 1A-1C is a schematic of a mate pair synthesis using droplets or multi-well plates and oligonucleotides tags which may comprise unique sequences (such unique sequences referred to as “index sequences” or “Idx”). The oligonucleotides are attached to each other, to form a unique label, using polymerase fill-in reactions. It is to be understood that a droplet or well may typically comprise an oligonucleotide tag of a single type, although it may contain (and most likely does contain) multiple copies of the same oligonucleotide tag.

FIG. 2 is a gel electrophoresis showing ligation of an adapter sequence in either a tube (T) or an emulsion droplet (E).

FIG. 3A1-3A2 is a schematic of a mate pair synthesis using droplets or multi-well plates and oligonucleotides tags which may comprise unique sequences (such unique sequences referred to as “index sequences” or “Idx”). The oligonucleotide tags are attached to each other, to form a unique label by virtue of the index sequences, using ligation.

FIG. 3B is a schematic illustrating a recursive indexing strategy of the invention.

FIG. 3C is a schematic illustrating index addition to either beads or DNA using multi-well plates.

FIG. 3D1-3D2 is a schematic illustrating index addition to either beads or DNA using droplets.

FIG. 3E is a schematic illustrating an approach to informatically associate mate pairs in accordance with the invention.

FIG. 4 provides bar graphs showing the results of 2-4 rounds of oligonucleotide tag attachment to demonstrate ligation efficiency.

FIG. 5A-5B shows various end products from a labeling synthesis as well as the frequency of each end product, including desired and spurious end products.

FIG. 6A-6C is a schematic of a plate-based approach to the generation of unique index combinations (labels). The unique labels are generated on particles or directly on nucleic acids (e.g., genomic DNA and cDNA). Oligonucleotide tags are present in the wells of multiwell plates. It is to be understood that a well may typically comprise an oligonucleotide tag of a single type, although it does contain multiple copies of the same oligonucleotide tag. Each well may comprise, at any given time, one or more beads or nucleic acid fragments.

FIG. 7 is a schematic of a plate-based approach to the generation of several pluralities of particles, wherein all the particles within a plurality are identically labeled.

FIG. 8A-8C is a schematic illustrating application of the labeling strategies of the invention to amplified fragments from the 16S region of a microbe.

FIG. 9A-9B is a schematic of a mate pair synthesis process using single stranded genomic DNA as the agent. Each droplet may comprise both strands of the genomic fragment. As shown in the Figure, the strands are identically labeled at one end.

FIG. 10A-10B is a schematic of a mate pair synthesis using droplets and Nextera transposomes as detectable tags.

FIG. 11 is a schematic illustrating the use of forked adapters. FIG. 11 discloses the ‘Adapters’ as SEQ ID NOS 2324-2327, respectively, in order of appearance, the ‘emPCR particles’ as SEQ ID NOS 2328-2329, respectively, in order of appearance and the ‘Primers’ as SEQ ID NOS 2330, 2331, 2329, 2328, 2332 and 2333, respectively, in order of appearance. FIG. 11 discloses the ‘emPCR Solution Phase Products’ as SEQ ID NOS 2324, 2325, 2334 and 2335, respectively, in order of appearance. FIG. 11 discloses the ‘emPCR bead-bound Products’ as SEQ ID NOS 2336-2339, respectively, in order of appearance, FIG. 11 discloses the ‘Sequencing set-up’ as SEQ ID NOS 2325, 2332, 2340, 2334, 2333 and 2327, respectively, in order of appearance.

FIG. 12 shows that the efficiency of DNA circularization (cyclization) decreases as fragment length increases.

FIG. 13A-13B is a schematic depicting the technique for polymerase mediated index addition.

FIG. 14 is a gel electrophoresis showing ligation of an adapter sequence in either a tube (T) or an emulsion droplet (E).

FIG. 15A-15B is a schematic depicting the technique for ligation mediated index addition.

FIG. 16 is a schematic depicting the technique for symmetric ligation-mediated index addition.

FIG. 17 is a flowchart detailing the criteria for barcode sequence selection.

FIG. 18 is a schematic depicting the methodology for informatically deriving mate pairs.

FIG. 19 shows catalyzing ligation by the controlled addition of MgCl₂.

FIG. 20 shows a stability determination of MgCl₂ in droplets.

FIG. 21 shows a determination of the optimal ratio of genomic Index:genomic DNA.

FIG. 22A-22B is a schematic depicting the process of symmetric indexing in emulsion.

FIG. 23 shows a proof of concept experiment.

FIG. 24 shows an analysis of E. coli proof of concept libraries.

FIG. 25 shows an analysis of lambda proof of concept libraries.

FIG. 26 shows a determination of symmetry of indexing in E. coli proof of concept libraries.

FIG. 27 shows the determination of uniformity of blunt-ended indexing.

FIG. 28 shows impact of ligation efficiency on bioinformatics end association.

FIG. 29 shows a redesign of index sequences. FIG. 29 discloses SEQ ID NOS 2341-2350, 2350, 2349, 2348, 2347, 2346, 2345, 2344, 2343 and 2342, respectively, in order of appearance.

FIG. 30 shows uniformity of indexing.

FIGS. 31-33 schematically illustrate a quantum dot RNA detection assay that can be used, inter alia, to detect and monitor pathogens.

FIG. 34 is a schematic illustrating a luminex bead based RNA detection assay that can be used, inter alia, to detect and monitor pathogens.

FIG. 35 is a schematic illustrating 16S amplicon tagging that can be used, inter alia, to distinguish different species of bacteria.

FIG. 36 shows amplification of fragment ends via transposome-based selection.

FIGS. 37a and 37b illustrate enrichment of ends via in vitro transcription. FIG. 37a discloses SEQ ID NOS 2351-2353, respectively, in order of appearance. FIG. 37b discloses SEQ ID NOS 2351, 2352, 2354-2357, 2357, 2354, 2355, 2358, 2359, 2356 and 2360, respectively, in order of appearance.

FIG. 38 shows amplification of ends via anchored PCR.

FIG. 39 shows producing multi-kilobase fragment reads from indexed DNA ends. FIG. 39 discloses SEQ ID NOS 2351-2352 and 2361, respectively, in order of appearance.

DETAILED DESCRIPTION OF INVENTION

The invention provides methods and compositions for uniquely labeling agents of interest including for example nucleic acids, such as DNA, peptides or proteins, cells, chemicals, etc. The ability to uniquely label agents has a number of applications, as contemplated by the invention, including but not limited to genomic sequencing, genomic assembly, screening of putative drugs and biologics, analysis of environmental samples to discover new organisms, labeling of individual elements of synthetic biology constructs, quality control analysis of reagents to verify purity, and analysis of downstream effects of various conditions on cells or cell components, etc. One of the major limitations of prior art labeling techniques is the limited number of available unique labels. Typically the number of agents to be labeled in any given application far exceeds the number of unique labels that are available. The methods of the invention can be used to synthesize essentially an infinite number of unique labels. Moreover, because of their nature, the labels can be easily detected and distinguished from each other, making them suitable for many applications and uses.

The methods of the invention easily and efficiently generate libraries of unique labels. Such libraries may be of any size, and are preferably large libraries including hundreds of thousands to billions of unique labels. The libraries of unique labels may be synthesized separately from agents and then associated with agents post-synthesis. Alternatively, unique labels may be synthesized in real-time (e.g., while in the presence of the agent) and in some instances the label synthesis is a function of the history of the agent. This means, in some instances, that synthesis of the label may occur while an agent is being exposed to one or more conditions. The invention therefore contemplates that the resultant label may store (or code) within it information about the agent (i.e., agent-specific information) including the origin or source of the agent, the relatedness of the agent to other agents, the genomic distance between two agents (e.g., in the case of genomic fragments), conditions to which the agent may have been exposed, and the like.

Some methods of the invention may comprise determining information about an agent based on the unique label associated with the agent. In some instances, determining information about the agent may comprise obtaining the nucleotide sequence of the unique label (i.e., sequencing the unique label). In other instances, determining information about the agent may comprise determining the presence, number and/or order of non-nucleic acid detectable moieties. In still other instances, determining information about the agent may comprise obtaining the nucleotide sequence of the unique label and determining the presence, number and/or order of non-nucleic acid detectable moieties. Methods for nucleic acid sequencing and detection of non-nucleic acid detectable moieties are known in the art and are described herein.

As used herein, “agent” or “agents” refers to any moiety or entity that can be associated with, including attached to, a unique label. An agent may be a single entity or it may be a plurality of entities. An agent may be a nucleic acid, a peptide, a protein, a cell, a cell lysate, a solid support, a polymer, a chemical, and the like, or an agent may be a plurality of any of the foregoing, or it may be a mixture of any of the foregoing. As an example, an agent may be nucleic acids (e.g., mRNA transcripts and/or genomic DNA fragments), solid supports such as beads or polymers, and/or proteins from a single cell or from a single cell population (e.g., a tumor or non-tumor tissue sample).

In some important embodiments, an agent is a nucleic acid. The nucleic acid agent may be single-stranded (ss) or double-stranded (ds), or it may be partially single-stranded and partially double-stranded. Nucleic acid agents include but are not limited to DNA such as genomic DNA fragments, PCR and other amplification products, RNA, cDNA, and the like. Nucleic acid agents may he fragments of larger nucleic acids such as but not limited to genomic DNA fragments.

Association of Labels and Agents

An agent of interest may be associated with a unique label. As used herein, “associated” refers to a relationship between the agent and the unique label such that the unique label may be used to identify the agent, identify the source or origin of the agent, identify one or more conditions to which the agent has been exposed, etc. A label that is associated with an agent may be, for example, physically attached to the agent, either directly or indirectly, or it may be in the same defined, typically physically separate, volume as the agent. A defined volume may be an emulsion droplet, a well (of for example a multiwell plate), a tube, a container, and the like. It is to be understood that the defined volume will typically contain only one agent and the label with which it is associated, although a volume containing multiple agents with multiple copies of the label is also contemplated depending on the application.

An agent may be associated with a single copy of a unique label or it may be associated with multiple copies of the same unique label including for example 2, 3, 4, 5, 6, 7, 8, 9, 10, 100, 1000, 10,000, 100,000 or more copies of the same unique label, In this context, the label is considered unique because it is different from labels associated with other, different agents.

Attachment of labels to agents may be direct or indirect. The attachment chemistry will depend on the nature of the agent and/or any derivatisation or functionalisation applied to the agent. For example, labels can be directly attached through covalent attachment. The label may include a moiety, which may be a non-nucleotide chemical modification, to facilitate attachment. By way of non-limiting example, the label may include methylated nucleotides, uracil bases, phosphorothioate groups, ribonucleotides, diol linkages, disulphide linkages, etc., to enable covalent attachment to an agent.

In another example, a label can be attached to an agent via a linker or in another indirect manner. Examples of linkers, include, but are not limited to, carbon-containing chains, polyethylene glycol (PEG), nucleic acids, monosaccharide units, and peptides. The linkers may be cleavable under certain conditions. Cleavable linkers are discussed in greater detail herein.

Methods for attaching nucleic acids to each other, as for example attaching nucleic acid labels to nucleic acid agents, are known in the art. Such methods include but are not limited to ligation, such as blunt end ligation or cohesive overhang ligation, and polymerase-mediated attachment methods (see, e.g., U.S. Patent Nos. 7863058 and 7754429; Green and Sambrook. Molecular Cloning: A Laboratory Manual, Fourth Edition, 2012; Current Protocols in Molecular Biology, and Current Protocols in Nucleic Acid Chemistry, all of which are incorporated herein by reference).

In some embodiments, oligonucleotide adapters are used to attach a unique label to an agent or to a solid support. In some embodiments, an oligonucleotide adapter may comprise one or more known sequences, e.g., an amplification sequence, a capture sequence, a primer sequence, and the like. In some embodiments, the adapter may comprise a thymidine (T) tail overhang. Methods for producing a thymidine tail overhang are known in the art, e.g., using terminal deoxynucleotide transferase (TdT) or a polymerase that adds a thymidine overhang at the termination of polymerization. In some embodiments, the oligonucleotide adapter may comprise a region that is forked. Examples of forked oligonucleotide adapters are described in Example 6.

In some embodiments, the adapter may comprise a capture or detection moiety. Examples of such moieties include, but are not limited to, fluorophores, microparticles such as quantum dots (Empodocles, et al., Nature 399:126-130, 1999), gold nanoparticles (Reichert et al, Anal. Chem, 72:6025-6029, 2000), microbeads (Lacoste et al, Proc. Natl. Acad. Sci. USA 97(17):9461-9466, 2000), biotin, DNP (dinitrophenyl), fucose, digoxigenin, and other moieties known to those skilled in the art. In some embodiments, the moiety is biotin.

A label and/or an agent may be attached to a solid support. In some instances, a label (or multiple copies of the same label) and the agent are attached to the same solid support. Examples of suitable solid supports include, but are not limited to, inert polymers (preferably non-nucleic acid polymers), beads, glass, or peptides. In some embodiments, the solid support is an inert polymer or a bead. The solid support may be functionalised to permit covalent attachment of the agent and/or label. Such functionalisation may comprise placing on the solid support reactive groups that permit covalent attachment to an agent and/or a label.

Labels and/or agents may be attached to each other or to solid supports using cleavable linkers. Cleavable linkers are known in the art and include, but are not limited to, TEV, trypsin, thrombin, cathepsin B, cathespin D, cathepsin K, caspase lumatrix metalloproteinase sequences, phosphodiester, phospholipid, ester,β-galactose, dialkyl dialkoxysilane, cyanoethyl group, sulfone, ethylene glycolyl disuccinate, 2-N-acyl nitrobenzenesulfonamide, a-thiophenylester, unsaturated vinyl sulfide, sulfonamide after activation, malondialdehyde (MDA)-indole derivative, levulinoyl ester, hydrazone, acylhydrazone, alkyl thioester, disulfide bridges, azo compounds, 2-Nitrobenzyl derivatives, phenacyl ester, 8-quinolinyl benzenesulfonate, coumarin, phosphotriester, bis-arylhydrazone, bimane bi-thiopropionic acidderivative, paramethoxybenzyl derivative, test-butylcarbamate analogue, dialkyl or diaryl dialkoxysilane, orthoester, acetal, aconityl, hydrazone, thiopropionate, phosphoramidate, imine, trityl, vinyl ether, polyketal, alkyl 2-(diphenylphosphino)benzoate derivatives, allyl ester, 8-hydroxyquinoline ester, picolinate ester, vicinal diols, and selenium compounds (see, e.g. Leriche G, Chisholm L, Wagner A. Cleavable Linkers in Chemical Biology. Bioorg Med Chem. 15;20(2):571-82. 2012, which is incorporated herein by reference). Cleavage conditions and reagents include, but are not limited to, enzymes, nucleophilic/basic reagents, reducing agents, photo-irradiation, electrophilic/acidic reagents, organometallic and metal reagents, and oxidizing reagents.

Detectable Oligonucleotide Tags

The unique labels of the invention are, at least in part, nucleic acid in nature, and are generated by sequentially attaching two or more detectable oligonucleotide tags to each other. As used herein, a detectable oligonucleotide tag is an oligonucleotide that can be detected by sequencing of its nucleotide sequence and/or by detecting non-nucleic acid detectable moieties it may be attached to.

The oligonucleotide tags are typically randomly selected from a diverse plurality of oligonucleotide tags. In some instances, an oligonucleotide tag may be present once in a plurality or it may be present multiple times in a plurality. In the latter instance, the plurality of tags may be comprised of a number of subsets each which may comprise a plurality of identical tags. In some important embodiments, these subsets are physically separate from each other. Physical separation may be achieved by providing the subsets in separate wells of a multiwell plate or separate droplets from an emulsion. It is the random selection and thus combination of oligonucleotide tags that results in a unique label. Accordingly, the number of distinct (i.e., different) oligonucleotide tags required to uniquely label a plurality of agents can be far less than the number of agents being labeled. This is particularly advantageous when the number of agents is large (e.g., when the agents are members of a library).

The oligonucleotide tags may be detectable by virtue of their nucleotide sequence, or by virtue of a non-nucleic acid detectable moiety that is attached to the oligonucleotide such as but not limited to a fluorophore, or by virtue of a combination of their nucleotide sequence and the non-nucleic acid detectable moiety.

As used herein, the term “oligonucleotide” refers to a nucleic acid such as deoxyribonucleic acid (DNA), ribonucleic acid (RNA), or DNA/RNA hybrids and includes analogs of either DNA or RNA made from nucleotide analogs known in the art (see, e.g. U.S. Patent or Patent Application Publications: U.S. Pat. Nos. 7,399,845, 7,741,457, 8,022,193, 7,569,686, 7,335,765, 7,314,923, 7,335,765, and 7,816,333, US 20110009471, the entire contents of each of which are incorporated herein by reference). Oligonucleotides may be single-stranded (such as sense or antisense oligonucleotides), double-stranded, or partially single-stranded and partially double-stranded.

In some embodiments, a detectable oligonucleotide tag may comprise one or more non-oligonucleotide detectable moieties. Examples of detectable moieties include, but are not limited to, fluorophores, microparticles including quantum dots (Empodocles, et al., Nature 399:126-130, 1999), gold nanoparticles (Reichert et al., Anal. Chem, 72:6025-6029, 2000), microbeads (Lacoste et al., Proc. Natl. Acad. Sci. USA 97(17):9461-9466, 2000), biotin, DNP (dinitrophenyl), fucose, digoxigenin, haptens, and other detectable moieties known to those skilled in the art. In some embodiments, the detectable moieties are quantum dots. Methods for detecting such moieties are described herein and/or are known in the art.

Thus, detectable oligonucleotide tags may be, but are not limited to, oligonucleotides which may comprise unique nucleotide sequences, oligonucleotides which may comprise detectable moieties, and oligonucleotides which may comprise both unique nucleotide sequences and detectable moieties.

A unique nucleotide sequence may be a nucleotide sequence that is different (and thus distinguishable) from the sequence of each detectable oligonucleotide tag in a plurality of detectable oligonucleotide tags. A unique nucleotide sequence may also be a nucleotide sequence that is different (and thus distinguishable) from the sequence of each detectable oligonucleotide tag in a first plurality of detectable oligonucleotide tags but identical to the sequence of at least one detectable oligonucleotide tag in a second plurality of detectable oligonucleotide tags. A unique sequence may differ from other sequences by multiple bases (or base pairs). The multiple bases may be contiguous or non-contiguous. Methods for obtaining nucleotide sequences (e.g., sequencing methods) are described herein and/or are known in the art.

In some embodiments, detectable oligonucleotide tags may comprise one or more of a ligation sequence, a priming sequence, a capture sequence, and a unique sequence (optionally referred to herein as an index sequence). A ligation sequence is a sequence complementary to a second nucleotide sequence which allows for ligation of the detectable oligonucleotide tag to another entity which may comprise the second nucleotide sequence, e.g., another detectable oligonucleotide tag or an oligonucleotide adapter. A priming sequence is a sequence complementary to a primer, e.g., an oligonucleotide primer used for an amplification reaction such as but not limited to PCR. A capture sequence is a sequence capable of being bound by a capture entity. A capture entity may be an oligonucleotide which may comprise a nucleotide sequence complementary to a capture sequence, e.g. a second detectable oligonucleotide tag or an oligonucleotide attached to a bead. A capture entity may also be any other entity capable of binding to the capture sequence, e.g., an antibody or peptide. An index sequence is a sequence which may comprise a unique nucleotide sequence and/or a detectable moiety as described above.

“Complementary” is a term which is used to indicate a sufficient degree of complementarily between two nucleotide sequences such that stable and specific binding occurs between one and preferably more bases (or nucleotides, as the terms are used interchangeably herein) of the two sequences. For example, if a nucleotide in a first nucleotide sequence is capable of hydrogen bonding with a nucleotide in second nucleotide sequence, then the bases are considered to be complementary to each other. Complete (i.e., 100%) complementarity between a first nucleotide sequence and a second nucleotide is preferable, but not required for ligation, priming, or capture sequences.

Table 1 below provides examples of certain oligonucleotide tags of the invention:

TABLE 1 SEQ SEQ SEQ ID ID ID NO: Tag NO: Full Oligo Sequence (Top) NO: Full Oligo Sequence (Bot)   1 GGATATCTGTGGATATCTGT 769 /5Phos/CAGAGGATATCTGTGGATATCTGT 1537 /5Phos/CGAAACAGATATCCACAGATATCC   2 GGCTGCCATAGGCTGCCATA 770 /5Phos/CAGAGGCTGCCATAGGCTGCCATA 1538 /5Phos/CGAATATGGCAGCCTATGGCAGCC   3 GGTATGTCAAGGTATGTCAA 771 /5Phos/CAGAGGTATGTCAAGGTATGTCAA 1539 /5Phos/CGAATTGACATACCTTGACATACC   4 GGTGAAGGACGGTGAAGGAC 772 /5Phos/CAGAGGTGAAGGACGGTGAAGGAC 1540 /5Phos/CGAAGTCCTTCACCGTCCTTCACC   5 GTACCAGCATGTACCAGCAT 773 /5Phos/CAGAGTACCAGCATGTACCAGCAT 1541 /5Phos/CGAAATGCTGGTACATGCTGGTAC   6 GTATACATCCGTATACATCC 774 /5Phos/CAGAGTATACATCCGTATACATCC 1542 /5Phos/CGAAGGATGTATACGGATGTATAC   7 GTATCGCTCAGTATCGCTCA 775 /5Phos/CAGAGTATCGCTCAGTATCGCTCA 1543 /5Phos/CGAATGAGCGATACTGAGCGATAC   8 GTCCGATGGAGTCCGATGGA 776 /5Phos/CAGAGTCCGATGGAGTCCGATGGA 1544 /5Phos/CGAATCCATCGGACTCCATCGGAC   9 GTGTGGAATTGTGTGGAATT 777 /5Phos/CAGAGTGTGGAATTGTGTGGAATT 1545 /5Phos/CGAAAATTCCACACAATTCCACAC  10 GTGTGGCAGAGTGTGGCAGA 778 /5Phos/CAGAGTGTGGCAGAGTGTGGCAGA 1546 /5Phos/CGAATCTGCCACACTCTGCCACAC  11 GTTACGGTGAGTTACGGTGA 779 /5Phos/CAGAGTTACGGTGAGTTACGGTGA 1547 /5Phos/CGAATCACCGTAACTCACCGTAAC  12 GTTCGTACATGTTCGTACAT 780 /5Phos/CAGAGTTCGTACATGTTCGTACAT 1548 /5Phos/CGAAATGTACGAACATGTACGAAC  13 TAACCGGTAATAACCGGTAA 781 /5Phos/CAGATAACCGGTAATAACCGGTAA 1549 /5Phos/CGAATTACCGGTTATTACCGGTTA  14 TACAGAGTCATACAGAGTCA 782 /5Phos/CAGATACAGAGTCATACAGAGTCA 1550 /5Phos/CGAATGACTCTGTATGACTCTGTA  15 TACCGAGATATACCGAGATA 783 /5Phos/CAGATACCGAGATATACCGAGATA 1551 /5Phos/CGAATATCTCGGTATATCTCGGTA  16 TACGCATCGCTACGCATCGC 784 /5Phos/CAGATACGCATCGCTACGCATCGC 1552 /5Phos/CGAAGCGATGCGTAGCGATGCGTA  17 TACGCGCTTGTACGCGCTTG 785 /5Phos/CAGATACGCGCTTGTACGCGCTTG 1553 /5Phos/CGAACAAGCGCGTACAAGCGCGTA  18 TAGACTTCACTAGACTTCAC 786 /5Phos/CAGATAGACTTCACTAGACTTCAC 1554 /5Phos/CGAAGTGAAGTCTAGTGAAGTCTA  19 TATCGCTTAGTATCGCTTAG 787 /5Phos/CAGATATCGCTTAGTATCGCTTAG 1555 /5Phos/CGAACTAAGCGATACTAAGCGATA  20 TCACGATCCGTCACGATCCG 788 /5Phos/CAGATCACGATCCGTCACGATCCG 1556 /5Phos/CGAACGGATCGTGACGGATCGTGA  21 TCAGCTTCGCTCAGCTTCGC 789 /5Phos/CAGATCAGCTTCGCTCAGCTTCGC 1557 /5Phos/CGAAGCGAAGCTGAGCGAAGCTGA  22 TCCGGACTTCTCCGGACTTC 790 /5Phos/CAGATCCGGACTTCTCCGGACTTC 1558 /5Phos/CGAAGAAGTCCGGAGAAGTCCGGA  23 TCCGGTATGGTCCGGTATGG 791 /5Phos/CAGATCCGGTATGGTCCGGTATGG 1559 /5Phos/CGAACCATACCGGACCATACCGGA  24 TCCGTGGTGATCCGTGGTGA 792 /5Phos/CAGATCCGTGGTGATCCGTGGTGA 1560 /5Phos/CGAATCACCACGGATCACCACGGA  25 TCCTCATCCATCCTCATCCA 793 /5Phos/CAGATCCTCATCCATCCTCATCCA 1561 /5Phos/CGAATGGATGAGGATGGATGAGGA  26 TCCTTCTGGATCCTTCTGGA 794 /5Phos/CAGATCCTTCTGGATCCTTCTGGA 1562 /5Phos/CGAATCCAGAAGGATCCAGAAGGA  27 TCGCTGTTGCTCGCTGTTGC 795 /5Phos/CAGATCGCTGTTGCTCGCTGTTGC 1563 /5Phos/CGAAGCAACAGCGAGCAACAGCGA  28 TCGGAGCTTGTCGGAGCTTG 796 /5Phos/CAGATCGGAGCTTGTCGGAGCTTG 1564 /5Phos/CGAACAAGCTCCGACAAGCTCCGA  29 TCGGCATGAGTCGGCATGAG 797 /5Phos/CAGATCGGCATGAGTCGGCATGAG 1565 /5Phos/CGAACTCATGCCGACTCATGCCGA  30 TCGGTGGAACTCGGTGGAAC 798 /5Phos/CAGATCGGTGGAACTCGGTGGAAC 1566 /5Phos/CGAAGTTCCACCGAGTTCCACCGA  31 TCGGTTGTAATCGGTTGTAA 799 /5Phos/CAGATCGGTTGTAATCGGTTGTAA 1567 /5Phos/CGAATTACAACCGATTACAACCGA  32 TCGTGTGGCATCGTGTGGCA 800 /5Phos/CAGATCGTGTGGCATCGTGTGGCA 1568 /5Phos/CGAATGCCACACGATGCCACACGA  33 TCTGTTCCGCTCTGTTCCGC 801 /5Phos/CAGATCTGTTCCGCTCTGTTCCGC 1569 /5Phos/CGAAGCGGAACAGAGCGGAACAGA  34 TCTTGGCGTCTCTTGGCGTC 802 /5Phos/CAGATCTTGGCGTCTCTTGGCGTC 1570 /5Phos/CGAAGACGCCAAGAGACGCCAAGA  35 TGATTGAGTCTGATTGAGTC 803 /5Phos/CAGATGATTGAGTCTGATTGAGTC 1571 /5Phos/CGAAGACTCAATCAGACTCAATCA  36 TGCGTTGGCATGCGTTGGCA 804 /5Phos/CAGATGCGTTGGCATGCGTTGGCA 1572 /5Phos/CGAATGCCAACGCATGCCAACGCA  37 TGGACATGCGTGGACATGCG 805 /5Phos/CAGATGGACATGCGTGGACATGCG 1573 /5Phos/CGAACGCATGTCCACGCATGTCCA  38 TGGCAAGCCATGGCAAGCCA 806 /5Phos/CAGATGGCAAGCCATGGCAAGCCA 1574 /5Phos/CGAATGGCTTGCCATGGCTTGCCA  39 TGGTTAACTGTGGTTAACTG 807 /5Phos/CAGATGGTTAACTGTGGTTAACTG 1575 /5Phos/CGAACAGTTAACCACAGTTAACCA  40 TGTACCTGAGTGTACCTGAG 808 /5Phos/CAGATGTACCTGAGTGTACCTGAG 1576 /5Phos/CGAACTCAGGTACACTCAGGTACA  41 TGTACTACAGTGTACTACAG 809 /5Phos/CAGATGTACTACAGTGTACTACAG 1577 /5Phos/CGAACTGTAGTACACTGTAGTACA  42 TGTCGGTTGCTGTCGGTTGC 810 /5Phos/CAGATGTCGGTTGCTGTCGGTTGC 1578 /5Phos/CGAAGCAACCGACAGCAACCGACA  43 TGTCTGTCGGTGTCTGTCGG 811 /5Phos/CAGATGTCTGTCGGTGTCTGTCGG 1579 /5Phos/CGAACCGACAGACACCGACAGACA  44 TGTGACTATCTGTGACTATC 812 /5Phos/CAGATGTGACTATCTGTGACTATC 1580 /5Phos/CGAAGATAGTCACAGATAGTCACA  45 TGTGAGTGCGTGTGAGTGCG 813 /5Phos/CAGATGTGAGTGCGTGTGAGTGCG 1581 /5Phos/CGAACGCACTCACACGCACTCACA  46 TGTGGTTCGCTGTGGTTCGC 814 /5Phos/CAGATGTGGTTCGCTGTGGTTCGC 1582 /5Phos/CGAAGCGAACCACAGCGAACCACA  47 TGTTCTCTACTGTTCTCTAC 815 /5Phos/CAGATGTTCTCTACTGTTCTCTAC 1583 /5Phos/CGAAGTAGAGAACAGTAGAGAACA  48 TTAGCCAGTCTTAGCCAGTC 816 /5Phos/CAGATTAGCCAGTCTTAGCCAGTC 1584 /5Phos/CGAAGACTGGCTAAGACTGGCTAA  49 TTCGCGAATATTCGCGAATA 817 /5Phos/CAGATTCGCGAATATTCGCGAATA 1585 /5Phos/CGAATATTCGCGAATATTCGCGAA  50 TTCGCGGTACTTCGCGGTAC 818 /5Phos/CAGATTCGCGGTACTTCGCGGTAC 1586 /5Phos/CGAAGTACCGCGAAGTACCGCGAA  51 TTCTATGCAGTTCTATGCAG 819 /5Phos/CAGATTCTATGCAGTTCTATGCAG 1587 /5Phos/CGAACTGCATAGAACTGCATAGAA  52 TTCTTACCGATTCTTACCGA 820 /5Phos/CAGATTCTTACCGATTCTTACCGA 1588 /5Phos/CGAATCGGTAAGAATCGGTAAGAA  53 TTGCTCTGGATTGCTCTGGA 821 /5Phos/CAGATTGCTCTGGATTGCTCTGGA 1589 /5Phos/CGAATCCAGAGCAATCCAGAGCAA  54 TTGTAACACCTTGTAACACC 822 /5Phos/CAGATTGTAACACCTTGTAACACC 1590 /5Phos/CGAAGGTGTTACAAGGTGTTACAA  55 AACAAGTTCCAACAAGTTCC 823 /5Phos/CAGAAACAAGTTCCAACAAGTTCC 1591 /5Phos/CGAAGGAACTTGTTGGAACTTGTT  56 AACAGCACGCAACAGCACGC 824 /5Phos/CAGAAACAGCACGCAACAGCACGC 1592 /5Phos/CGAAGCGTGCTGTTGCGTGCTGTT  57 AACGTGCGGTAACGTGCGGT 825 /5Phos/CAGAAACGTGCGGTAACGTGCGGT 1593 /5Phos/CGAAACCGCACGTTACCGCACGTT  58 AAGAGCGATGAAGAGCGATG 826 /5Phos/CAGAAAGAGCGATGAAGAGCGATG 1594 /5Phos/CGAACATCGCTCTTCATCGCTCTT  59 AAGGAATTCCAAGGAATTCC 827 /5Phos/CAGAAAGGAATTCCAAGGAATTCC 1595 /5Phos/CGAAGGAATTCCTTGGAATTCCTT  60 AAGTGAGGCGAAGTGAGGCG 828 /5Phos/CAGAAAGTGAGGCGAAGTGAGGCG 1596 /5Phos/CGAACGCCTCACTTCGCCTCACTT  61 AATACGCGATAATACGCGAT 829 /5Phos/CAGAAATACGCGATAATACGCGAT 1597 /5Phos/CGAAATCGCGTATTATCGCGTATT  62 AATAGGTTGGAATAGGTTGG 830 /5Phos/CAGAAATAGGTTGGAATAGGTTGG 1598 /5Phos/CGAACCAACCTATTCCAACCTATT  63 AATCGAAGCTAATCGAAGCT 831 /5Phos/CAGAAATCGAAGCTAATCGAAGCT 1599 /5Phos/CGAAAGCTTCGATTAGCTTCGATT  64 ACACTACGATACACTACGAT 832 /5Phos/CAGAACACTACGATACACTACGAT 1600 /5Phos/CGAAATCGTAGTGTATCGTAGTGT  65 ACACTCAGCCACACTCAGCC 833 /5Phos/CAGAACACTCAGCCACACTCAGCC 1601 /5Phos/CGAAGGCTGAGTGTGGCTGAGTGT  66 ACATCGAGCCACATCGAGCC 834 /5Phos/CAGAACATCGAGCCACATCGAGCC 1602 /5Phos/CGAAGGCTCGATGTGGCTCGATGT  67 ACATTATGCGACATTATGCG 835 /5Phos/CAGAACATTATGCGACATTATGCG 1603 /5Phos/CGAACGCATAATGTCGCATAATGT  68 ACCAGCAACTACCAGCAACT 836 /5Phos/CAGAACCAGCAACTACCAGCAACT 1604 /5Phos/CGAAAGTTGCTGGTAGTTGCTGGT  69 ACCGAACACGACCGAACACG 837 /5Phos/CAGAACCGAACACGACCGAACACG 1605 /5Phos/CGAACGTGTTCGGTCGTGTTCGGT  70 ACCGAACGGTACCGAACGGT 838 /5Phos/CAGAACCGAACGGTACCGAACGGT 1606 /5Phos/CGAAACCGTTCGGTACCGTTCGGT  71 ACGAGTGGCTACGAGTGGCT 839 /5Phos/CAGAACGAGTGGCTACGAGTGGCT 1607 /5Phos/CGAAAGCCACTCGTAGCCACTCGT  72 ACGGTTACGGACGGTTACGG 840 /5Phos/CAGAACGGTTACGGACGGTTACGG 1608 /5Phos/CGAACCGTAACCGTCCGTAACCGT  73 ACGTAAGCGCACGTAAGCGC 841 /5Phos/CAGAACGTAAGCGCACGTAAGCGC 1609 /5Phos/CGAAGCGCTTACGTGCGCTTACGT  74 ACTATGTGCTACTATGTGCT 842 /5Phos/CAGAACTATGTGCTACTATGTGCT 1610 /5Phos/CGAAAGCACATAGTAGCACATAGT  75 ACTGGAGTCCACTGGAGTCC 843 /5Phos/CAGAACTGGAGTCCACTGGAGTCC 1611 /5Phos/CGAAGGACTCCAGTGGACTCCAGT  76 ACTGTACTTCACTGTACTTC 844 /5Phos/CAGAACTGTACTTCACTGTACTTC 1612 /5Phos/CGAAGAAGTACAGTGAAGTACAGT  77 AGAAGTCTGCAGAAGTCTGC 845 /5Phos/CAGAAGAAGTCTGCAGAAGTCTGC 1613 /5Phos/CGAAGCAGACTTCTGCAGACTTCT  78 AGACGCGAGTAGACGCGAGT 846 /5Phos/CAGAAGACGCGAGTAGACGCGAGT 1614 /5Phos/CGAAACTCGCGTCTACTCGCGTCT  79 AGACTGTGCTAGACTGTGCT 847 /5Phos/CAGAAGACTGTGCTAGACTGTGCT 1615 /5Phos/CGAAAGCACAGTCTAGCACAGTCT  80 AGAGTACGCCAGAGTACGCC 848 /5Phos/CAGAAGAGTACGCCAGAGTACGCC 1616 /5Phos/CGAAGGCGTACTCTGGCGTACTCT  81 AGATCGACTGAGATCGACTG 849 /5Phos/CAGAAGATCGACTGAGATCGACTG 1617 /5Phos/CGAACAGTCGATCTCAGTCGATCT  82 AGATTCGGCCAGATTCGGCC 850 /5Phos/CAGAAGATTCGGCCAGATTCGGCC 1618 /5Phos/CGAAGGCCGAATCTGGCCGAATCT  83 AGCAAGTGCTAGCAAGTGCT 851 /5Phos/CAGAAGCAAGTGCTAGCAAGTGCT 1619 /5Phos/CGAAAGCACTTGCTAGCACTTGCT  84 AGCCATTGCGAGCCATTGCG 852 /5Phos/CAGAAGCCATTGCGAGCCATTGCG 1620 /5Phos/CGAACGCAATGGCTCGCAATGGCT  85 AGCGGACAGTAGCGGACAGT 853 /5Phos/CAGAAGCGGACAGTAGCGGACAGT 1621 /5Phos/CGAAACTGTCCGCTACTGTCCGCT  86 AGCGTAAGCGAGCGTAAGCG 854 /5Phos/CAGAAGCGTAAGCGAGCGTAAGCG 1622 /5Phos/CGAACGCTTACGCTCGCTTACGCT  87 AGCTATTCTCAGCTATTCTC 855 /5Phos/CAGAAGCTATTCTCAGCTATTCTC 1623 /5Phos/CGAAGAGAATAGCTGAGAATAGCT  88 AGCTTATACGAGCTTATACG 856 /5Phos/CAGAAGCTTATACGAGCTTATACG 1624 /5Phos/CGAACGTATAAGCTCGTATAAGCT  89 AGGACAGATGAGGACAGATG 857 /5Phos/CAGAAGGACAGATGAGGACAGATG 1625 /5Phos/CGAACATCTGTCCTCATCTGTCCT  90 AGGATCAGATAGGATCAGAT 858 /5Phos/CAGAAGGATCAGATAGGATCAGAT 1626 /5Phos/CGAAATCTGATCCTATCTGATCCT  91 AGGCTGAAGGAGGCTGAAGG 859 /5Phos/CAGAAGGCTGAAGGAGGCTGAAGG 1627 /5Phos/CGAACCTTCAGCCTCCTTCAGCCT  92 AGGTACGAGGAGGTACGAGG 860 /5Phos/CAGAAGGTACGAGGAGGTACGAGG 1628 /5Phos/CGAACCTCGTACCTCCTCGTACCT  93 AGGTAGGCTCAGGTAGGCTC 861 /5Phos/CAGAAGGTAGGCTCAGGTAGGCTC 1629 /5Phos/CGAAGAGCCTACCTGAGCCTACCT  94 AGGTGAACGGAGGTGAACGG 862 /5Phos/CAGAAGGTGAACGGAGGTGAACGG 1630 /5Phos/CGAACCGTTCACCTCCGTTCACCT  95 AGGTGCCAATAGGTGCCAAT 863 /5Phos/CAGAAGGTGCCAATAGGTGCCAAT 1631 /5Phos/CGAAATTGGCACCTATTGGCACCT  96 AGGTTCAACGAGGTTCAACG 864 /5Phos/CAGAAGGTTCAACGAGGTTCAACG 1632 /5Phos/CGAACGTTGAACCTCGTTGAACCT  97 AGTCACTCGCAGTCACTCGC 865 /5Phos/CAGAAGTCACTCGCAGTCACTCGC 1633 /5Phos/CGAAGCGAGTGACTGCGAGTGACT  98 AGTCGTGGTGAGTCGTGGTG 866 /5Phos/CAGAAGTCGTGGTGAGTCGTGGTG 1634 /5Phos/CGAACACCACGACTCACCACGACT  99 AGTGGAGGAGAGTGGAGGAG 867 /5Phos/CAGAAGTGGAGGAGAGTGGAGGAG 1635 /5Phos/CGAACTCCTCCACTCTCCTCCACT 100 AGTTGAGCGCAGTTGAGCGC 868 /5Phos/CAGAAGTTGAGCGCAGTTGAGCGC 1636 /5Phos/CGAAGCGCTCAACTGCGCTCAACT 101 AGTTGATGGTAGTTGATGGT 869 /5Phos/CAGAAGTTGATGGTAGTTGATGGT 1637 /5Phos/CGAAACCATCAACTACCATCAACT 102 ATAACACAGCATAACACAGC 870 /5Phos/CAGAATAACACAGCATAACACAGC 1638 /5Phos/CGAAGCTGTGTTATGCTGTGTTAT 103 ATAAGGTCCGATAAGGTCCG 871 /5Phos/CAGAATAAGGTCCGATAAGGTCCG 1639 /5Phos/CGAACGGACCTTATCGGACCTTAT 104 ATACAGTCAGATACAGTCAG 872 /5Phos/CAGAATACAGTCAGATACAGTCAG 1640 /5Phos/CGAACTGACTGTATCTGACTGTAT 105 ATACCGGCCTATACCGGCCT 873 /5Phos/CAGAATACCGGCCTATACCGGCCT 1641 /5Phos/CGAAAGGCCGGTATAGGCCGGTAT 106 ATAGCAGGATATAGCAGGAT 874 /5Phos/CAGAATAGCAGGATATAGCAGGAT 1642 /5Phos/CGAAATCCTGCTATATCCTGCTAT 107 ATAGCGTTACATAGCGTTAC 875 /5Phos/CAGAATAGCGTTACATAGCGTTAC 1643 /5Phos/CGAAGTAACGCTATGTAACGCTAT 108 ATAGTCCAACATAGTCCAAC 876 /5Phos/CAGAATAGTCCAACATAGTCCAAC 1644 /5Phos/CGAAGTTGGACTATGTTGGACTAT 109 ATATCGGCGGATATCGGCGG 877 /5Phos/CAGAATATCGGCGGATATCGGCGG 1645 /5Phos/CGAACCGCCGATATCCGCCGATAT 110 ATCCGTGATGATCCGTGATG 878 /5Phos/CAGAATCCGTGATGATCCGTGATG 1646 /5Phos/CGAACATCACGGATCATCACGGAT 111 ATCGTACCGGATCGTACCGG 879 /5Phos/CAGAATCGTACCGGATCGTACCGG 1647 /5Phos/CGAACCGGTACGATCCGGTACGAT 112 ATCGTTACTGATCGTTACTG 880 /5Phos/CAGAATCGTTACTGATCGTTACTG 1648 /5Phos/CGAACAGTAACGATCAGTAACGAT 113 ATGAAGATGCATGAAGATGC 881 /5Phos/CAGAATGAAGATGCATGAAGATGC 1649 /5Phos/CGAAGCATCTTCATGCATCTTCAT 114 ATGGCGTGGTATGGCGTGGT 882 /5Phos/CAGAATGGCGTGGTATGGCGTGGT 1650 /5Phos/CGAAACCACGCCATACCACGCCAT 115 ATGTTGAGCGATGTTGAGCG 883 /5Phos/CAGAATGTTGAGCGATGTTGAGCG 1651 /5Phos/CGAACGCTCAACATCGCTCAACAT 116 ATTAGCTGTCATTAGCTGTC 884 /5Phos/CAGAATTAGCTGTCATTAGCTGTC 1652 /5Phos/CGAAGACAGCTAATGACAGCTAAT 117 ATTCGCGTGCATTCGCGTGC 885 /5Phos/CAGAATTCGCGTGCATTCGCGTGC 1653 /5Phos/CGAAGCACGCGAATGCACGCGAAT 118 ATTGCGCTCCATTGCGCTCC 886 /5Phos/CAGAATTGCGCTCCATTGCGCTCC 1654 /5Phos/CGAAGGAGCGCAATGGAGCGCAAT 119 ATTGTGTTGCATTGTGTTGC 887 /5Phos/CAGAATTGTGTTGCATTGTGTTGC 1655 /5Phos/CGAAGCAACACAATGCAACACAAT 120 CAAGACGAATCAAGACGAAT 888 /5Phos/CAGACAAGACGAATCAAGACGAAT 1656 /5Phos/CGAAATTCGTCTTGATTCGTCTTG 121 CACGCACTGTCACGCACTGT 889 /5Phos/CAGACACGCACTGTCACGCACTGT 1657 /5Phos/CGAAACAGTGCGTGACAGTGCGTG 122 CACGGAGTAGCACGGAGTAG 890 /5Phos/CAGACACGGAGTAGCACGGAGTAG 1658 /5Phos/CGAACTACTCCGTGCTACTCCGTG 123 CACGGTATCGCACGGTATCG 891 /5Phos/CAGACACGGTATCGCACGGTATCG 1659 /5Phos/CGAACGATACCGTGCGATACCGTG 124 CACTCGGATTCACTCGGATT 892 /5Phos/CAGACACTCGGATTCACTCGGATT 1660 /5Phos/CGAAAATCCGAGTGAATCCGAGTG 125 CACTTGAGTACACTTGAGTA 893 /5Phos/CAGACACTTGAGTACACTTGAGTA 1661 /5Phos/CGAATACTCAAGTGTACTCAAGTG 126 CAGCCTCAGTCAGCCTCAGT 894 /5Phos/CAGACAGCCTCAGTCAGCCTCAGT 1662 /5Phos/CGAAACTGAGGCTGACTGAGGCTG 127 CAGCTCCAAGCAGCTCCAAG 895 /5Phos/CAGACAGCTCCAAGCAGCTCCAAG 1663 /5Phos/CGAACTTGGAGCTGCTTGGAGCTG 128 CATCGAGGAGCATCGAGGAG 896 /5Phos/CAGACATCGAGGAGCATCGAGGAG 1664 /5Phos/CGAACTCCTCGATGCTCCTCGATG 129 CATTGGCCGTCATTGGCCGT 897 /5Phos/CAGACATTGGCCGTCATTGGCCGT 1665 /5Phos/CGAAACGGCCAATGACGGCCAATG 130 CCAGAACTGGCCAGAACTGG 898 /5Phos/CAGACCAGAACTGGCCAGAACTGG 1666 /5Phos/CGAACCAGTTCTGGCCAGTTCTGG 131 CCAGATACGGCCAGATACGG 899 /5Phos/CAGACCAGATACGGCCAGATACGG 1667 /5Phos/CGAACCGTATCTGGCCGTATCTGG 132 CCAGGATCCACCAGGATCCA 900 /5Phos/CAGACCAGGATCCACCAGGATCCA 1668 /5Phos/CGAATGGATCCTGGTGGATCCTGG 133 CCAGGATGTTCCAGGATGTT 901 /5Phos/CAGACCAGGATGTTCCAGGATGTT 1669 /5Phos/CGAAAACATCCTGGAACATCCTGG 134 CCGAGCATGTCCGAGCATGT 902 /5Phos/CAGACCGAGCATGTCCGAGCATGT 1670 /5Phos/CGAAACATGCTCGGACATGCTCGG 135 CCGGAGTGTTCCGGAGTGTT 903 /5Phos/CAGACCGGAGTGTTCCGGAGTGTT 1671 /5Phos/CGAAAACACTCCGGAACACTCCGG 136 CCGGTACCATCCGGTACCAT 904 /5Phos/CAGACCGGTACCATCCGGTACCAT 1672 /5Phos/CGAAATGGTACCGGATGGTACCGG 137 CCGTCTAAGGCCGTCTAAGG 905 /5Phos/CAGACCGTCTAAGGCCGTCTAAGG 1673 /5Phos/CGAACCTTAGACGGCCTTAGACGG 138 CCTCCATTAACCTCCATTAA 906 /5Phos/CAGACCTCCATTAACCTCCATTAA 1674 /5Phos/CGAATTAATGGAGGTTAATGGAGG 139 CCTCCTGACTCCTCCTGACT 907 /5Phos/CAGACCTCCTGACTCCTCCTGACT 1675 /5Phos/CGAAAGTCAGGAGGAGTCAGGAGG 140 CCTCTGCTCTCCTCTGCTCT 908 /5Phos/CAGACCTCTGCTCTCCTCTGCTCT 1676 /5Phos/CGAAAGAGCAGAGGAGAGCAGAGG 141 CCTGCCTTGTCCTGCCTTGT 909 /5Phos/CAGACCTGCCTTGTCCTGCCTTGT 1677 /5Phos/CGAAACAAGGCAGGACAAGGCAGG 142 CCTGGCCATTCCTGGCCATT 910 /5Phos/CAGACCTGGCCATTCCTGGCCATT 1678 /5Phos/CGAAAATGGCCAGGAATGGCCAGG 143 CCTTAACGCGCCTTAACGCG 911 /5Phos/CAGACCTTAACGCGCCTTAACGCG 1679 /5Phos/CGAACGCGTTAAGGCGCGTTAAGG 144 CGACCTGTCTCGACCTGTCT 912 /5Phos/CAGACGACCTGTCTCGACCTGTCT 1680 /5Phos/CGAAAGACAGGTCGAGACAGGTCG 145 CGCGTTACGTCGCGTTACGT 913 /5Phos/CAGACGCGTTACGTCGCGTTACGT 1681 /5Phos/CGAAACGTAACGCGACGTAACGCG 146 CGGCAGTTCACGGCAGTTCA 914 /5Phos/CAGACGGCAGTTCACGGCAGTTCA 1682 /5Phos/CGAATGAACTGCCGTGAACTGCCG 147 CGGCCATTAGCGGCCATTAG 915 /5Phos/CAGACGGCCATTAGCGGCCATTAG 1683 /5Phos/CGAACTAATGGCCGCTAATGGCCG 148 CGTATTGCATCGTATTGCAT 916 /5Phos/CAGACGTATTGCATCGTATTGCAT 1684 /5Phos/CGAAATGCAATACGATGCAATACG 149 CTACGACCGTCTACGACCGT 917 /5Phos/CAGACTACGACCGTCTACGACCGT 1685 /5Phos/CGAAACGGTCGTAGACGGTCGTAG 150 CTAGGAAGGTCTAGGAAGGT 918 /5Phos/CAGACTAGGAAGGTCTAGGAAGGT 1686 /5Phos/CGAAACCTTCCTAGACCTTCCTAG 151 CTAGTCCTGTCTAGTCCTGT 919 /5Phos/CAGACTAGTCCTGTCTAGTCCTGT 1687 /5Phos/CGAAACAGGACTAGACAGGACTAG 152 CTAGTGGAGGCTAGTGGAGG 920 /5Phos/CAGACTAGTGGAGGCTAGTGGAGG 1688 /5Phos/CGAACCTCCACTAGCCTCCACTAG 153 CTCGCAGAGTCTCGCAGAGT 921 /5Phos/CAGACTCGCAGAGTCTCGCAGAGT 1689 /5Phos/CGAAACTCTGCGAGACTCTGCGAG 154 CTCGCTTCGTCTCGCTTCGT 922 /5Phos/CAGACTCGCTTCGTCTCGCTTCGT 1690 /5Phos/CGAAACGAAGCGAGACGAAGCGAG 155 CTCGTTAGCGCTCGTTAGCG 923 /5Phos/CAGACTCGTTAGCGCTCGTTAGCG 1691 /5Phos/CGAACGCTAACGAGCGCTAACGAG 156 CTCTTCCAAGCTCTTCCAAG 924 /5Phos/CAGACTCTTCCAAGCTCTTCCAAG 1692 /5Phos/CGAACTTGGAAGAGCTTGGAAGAG 157 CTGCTTCAATCTGCTTCAAT 925 /5Phos/CAGACTGCTTCAATCTGCTTCAAT 1693 /5Phos/CGAAATTGAAGCAGATTGAAGCAG 158 CTGGTATCAACTGGTATCAA 926 /5Phos/CAGACTGGTATCAACTGGTATCAA 1694 /5Phos/CGAATTGATACCAGTTGATACCAG 159 CTGTCTTCGGCTGTCTTCGG 927 /5Phos/CAGACTGTCTTCGGCTGTCTTCGG 1695 /5Phos/CGAACCGAAGACAGCCGAAGACAG 160 CTTCATGACGCTTCATGACG 928 /5Phos/CAGACTTCATGACGCTTCATGACG 1696 /5Phos/CGAACGTCATGAAGCGTCATGAAG 161 CTTCGGCAGTCTTCGGCAGT 929 /5Phos/CAGACTTCGGCAGTCTTCGGCAGT 1697 /5Phos/CGAAACTGCCGAAGACTGCCGAAG 162 CTTGACCGGTCTTGACCGGT 930 /5Phos/CAGACTTGACCGGTCTTGACCGGT 1698 /5Phos/CGAAACCGGTCAAGACCGGTCAAG 163 CTTGCCTATTCTTGCCTATT 931 /5Phos/CAGACTTGCCTATTCTTGCCTATT 1699 /5Phos/CGAAAATAGGCAAGAATAGGCAAG 164 GAACTTGTGAGAACTTGTGA 932 /5Phos/CAGAGAACTTGTGAGAACTTGTGA 1700 /5Phos/CGAATCACAAGTTCTCACAAGTTC 165 GAAGCATTCTGAAGCATTCT 933 /5Phos/CAGAGAAGCATTCTGAAGCATTCT 1701 /5Phos/CGAAAGAATGCTTCAGAATGCTTC 166 GAATCCATTCGAATCCATTC 934 /5Phos/CAGAGAATCCATTCGAATCCATTC 1702 /5Phos/CGAAGAATGGATTCGAATGGATTC 167 GACGCCTGTTGACGCCTGTT 935 /5Phos/CAGAGACGCCTGTTGACGCCTGTT 1703 /5Phos/CGAAAACAGGCGTCAACAGGCGTC 168 GACGTAGGACGACGTAGGAC 936 /5Phos/CAGAGACGTAGGACGACGTAGGAC 1704 /5Phos/CGAAGTCCTACGTCGTCCTACGTC 169 GACTAATGGTGACTAATGGT 937 /5Phos/CAGAGACTAATGGTGACTAATGGT 1705 /5Phos/CGAAACCATTAGTCACCATTAGTC 170 GAGCCTCCTTGAGCCTCCTT 938 /5Phos/CAGAGAGCCTCCTTGAGCCTCCTT 1706 /5Phos/CGAAAAGGAGGCTCAAGGAGGCTC 171 GAGCGTCTACGAGCGTCTAC 939 /5Phos/CAGAGAGCGTCTACGAGCGTCTAC 1707 /5Phos/CGAAGTAGACGCTCGTAGACGCTC 172 GAGGATAGGCGAGGATAGGC 940 /5Phos/CAGAGAGGATAGGCGAGGATAGGC 1708 /5Phos/CGAAGCCTATCCTCGCCTATCCTC 173 GAGTGCCATCGAGTGCCATC 941 /5Phos/CAGAGAGTGCCATCGAGTGCCATC 1709 /5Phos/CGAAGATGGCACTCGATGGCACTC 174 GAGTGGATCTGAGTGGATCT 942 /5Phos/CAGAGAGTGGATCTGAGTGGATCT 1710 /5Phos/CGAAAGATCCACTCAGATCCACTC 175 GAGTGGTAGCGAGTGGTAGC 943 /5Phos/CAGAGAGTGGTAGCGAGTGGTAGC 1711 /5Phos/CGAAGCTACCACTCGCTACCACTC 176 GAGTTAGAGAGAGTTAGAGA 944 /5Phos/CAGAGAGTTAGAGAGAGTTAGAGA 1712 /5Phos/CGAATCTCTAACTCTCTCTAACTC 177 GCACATCTGCGCACATCTGC 945 /5Phos/CAGAGCACATCTGCGCACATCTGC 1713 /5Phos/CGAAGCAGATGTGCGCAGATGTGC 178 GCACCATTACGCACCATTAC 946 /5Phos/CAGAGCACCATTACGCACCATTAC 1714 /5Phos/CGAAGTAATGGTGCGTAATGGTGC 179 GCAGCCTATTGCAGCCTATT 947 /5Phos/CAGAGCAGCCTATTGCAGCCTATT 1715 /5Phos/CGAAAATAGGCTGCAATAGGCTGC 180 GCAGTATCAAGCAGTATCAA 948 /5Phos/CAGAGCAGTATCAAGCAGTATCAA 1716 /5Phos/CGAATTGATACTGCTTGATACTGC 181 GCCGTCGTTAGCCGTCGTTA 949 /5Phos/CAGAGCCGTCGTTAGCCGTCGTTA 1717 /5Phos/CGAATAACGACGGCTAACGACGGC 182 GCCTGAGCTAGCCTGAGCTA 950 /5Phos/CAGAGCCTGAGCTAGCCTGAGCTA 1718 /5Phos/CGAATAGCTCAGGCTAGCTCAGGC 183 GCGCAAGCAAGCGCAAGCAA 951 /5Phos/CAGAGCGCAAGCAAGCGCAAGCAA 1719 /5Phos/CGAATTGCTTGCGCTTGCTTGCGC 184 GCGTTACGACGCGTTACGAC 952 /5Phos/CAGAGCGTTACGACGCGTTACGAC 1720 /5Phos/CGAAGTCGTAACGCGTCGTAACGC 185 GCGTTGGATCGCGTTGGATC 953 /5Phos/CAGAGCGTTGGATCGCGTTGGATC 1721 /5Phos/CGAAGATCCAACGCGATCCAACGC 186 GCTAGTCGCAGCTAGTCGCA 954 /5Phos/CAGAGCTAGTCGCAGCTAGTCGCA 1722 /5Phos/CGAATGCGACTAGCTGCGACTAGC 187 GCTCACTACCGCTCACTACC 955 /5Phos/CAGAGCTCACTACCGCTCACTACC 1723 /5Phos/CGAAGGTAGTGAGCGGTAGTGAGC 188 GCTCGAATTAGCTCGAATTA 956 /5Phos/CAGAGCTCGAATTAGCTCGAATTA 1724 /5Phos/CGAATAATTCGAGCTAATTCGAGC 189 GCTCGATTCCGCTCGATTCC 957 /5Phos/CAGAGCTCGATTCCGCTCGATTCC 1725 /5Phos/CGAAGGAATCGAGCGGAATCGAGC 190 GCTGAGGATCGCTGAGGATC 958 /5Phos/CAGAGCTGAGGATCGCTGAGGATC 1726 /5Phos/CGAAGATCCTCAGCGATCCTCAGC 191 GCTTCATTCTGCTTCATTCT 959 /5Phos/CAGAGCTTCATTCTGCTTCATTCT 1727 /5Phos/CGAAAGAATGAAGCAGAATGAAGC 192 GCTTGCTATTGCTTGCTATT 960 /5Phos/CAGAGCTTGCTATTGCTTGCTATT 1728 /5Phos/CGAAAATAGCAAGCAATAGCAAGC 193 GCTTGGTTGCGCTTGGTTGC 961 /5Phos/TTCGGCTTGGTTGCGCTTGGTTGC 1729 /5Phos/GTCAGCAACCAAGCGCAACCAAGC 194 GGAGTGGTTCGGAGTGGTTC 962 /5Phos/TTCGGGAGTGGTTCGGAGTGGTTC 1730 /5Phos/GTCAGAACCACTCCGAACCACTCC 195 GGATAATACCGGATAATACC 963 /5Phos/TTCGGGATAATACCGGATAATACC 1731 /5Phos/GTCAGGTATTATCCGGTATTATCC 196 GGATCGTGGTGGATCGTGGT 964 /5Phos/TTCGGGATCGTGGTGGATCGTGGT 1732 /5Phos/GTCAACCACGATCCACCACGATCC 197 GGATGATTGTGGATGATTGT 965 /5Phos/TTCGGGATGATTGTGGATGATTGT 1733 /5Phos/GTCAACAATCATCCACAATCATCC 198 GGATGCGTTCGGATGCGTTC 966 /5Phos/TTCGGGATGCGTTCGGATGCGTTC 1734 /5Phos/GTCAGAACGCATCCGAACGCATCC 199 GGCGAATGTCGGCGAATGTC 967 /5Phos/TTCGGGCGAATGTCGGCGAATGTC 1735 /5Phos/GTCAGACATTCGCCGACATTCGCC 200 GGCGATTGGTGGCGATTGGT 968 /5Phos/TTCGGGCGATTGGTGGCGATTGGT 1736 /5Phos/GTCAACCAATCGCCACCAATCGCC 201 GGCGGTATCAGGCGGTATCA 969 /5Phos/TTCGGGCGGTATCAGGCGGTATCA 1737 /5Phos/GTCATGATACCGCCTGATACCGCC 202 GGCTATCCACGGCTATCCAC 970 /5Phos/TTCGGGCTATCCACGGCTATCCAC 1738 /5Phos/GTCAGTGGATAGCCGTGGATAGCC 203 GGCTATTACAGGCTATTACA 971 /5Phos/TTCGGGCTATTACAGGCTATTACA 1739 /5Phos/GTCATGTAATAGCCTGTAATAGCC 204 GGCTGAACTCGGCTGAACTC 972 /5Phos/TTCGGGCTGAACTCGGCTGAACTC 1740 /5Phos/GTCAGAGTTCAGCCGAGTTCAGCC 205 GGTACAGTCAGGTACAGTCA 973 /5Phos/TTCGGGTACAGTCAGGTACAGTCA 1741 /5Phos/GTCATGACTGTACCTGACTGTACC 206 GGTCGAACCTGGTCGAACCT 974 /5Phos/TTCGGGTCGAACCTGGTCGAACCT 1742 /5Phos/GTCAAGGTTCGACCAGGTTCGACC 207 GGTCTCTCGTGGTCTCTCGT 975 /5Phos/TTCGGGTCTCTCGTGGTCTCTCGT 1743 /5Phos/GTCAACGAGAGACCACGAGAGACC 208 GGTGCTTGTCGGTGCTTGTC 976 /5Phos/TTCGGGTGCTTGTCGGTGCTTGTC 1744 /5Phos/GTCAGACAAGCACCGACAAGCACC 209 GGTTCCACTTGGTTCCACTT 977 /5Phos/TTCGGGTTCCACTTGGTTCCACTT 1745 /5Phos/GTCAAAGTGGAACCAAGTGGAACC 210 GGTTGCATCCGGTTGCATCC 978 /5Phos/TTCGGGTTGCATCCGGTTGCATCC 1746 /5Phos/GTCAGGATGCAACCGGATGCAACC 211 GGTTGGACGTGGTTGGACGT 979 /5Phos/TTCGGGTTGGACGTGGTTGGACGT 1747 /5Phos/GTCAACGTCCAACCACGTCCAACC 212 GTAAGAGCAAGTAAGAGCAA 980 /5Phos/TTCGGTAAGAGCAAGTAAGAGCAA 1748 /5Phos/GTCATTGCTCTTACTTGCTCTTAC 213 GTAAGGCTTAGTAAGGCTTA 981 /5Phos/TTCGGTAAGGCTTAGTAAGGCTTA 1749 /5Phos/GTCATAAGCCTTACTAAGCCTTAC 214 GTAGTCCTCAGTAGTCCTCA 982 /5Phos/TTCGGTAGTCCTCAGTAGTCCTCA 1750 /5Phos/GTCATGAGGACTACTGAGGACTAC 215 GTCCGGTTCTGTCCGGTTCT 983 /5Phos/TTCGGTCCGGTTCTGTCCGGTTCT 1751 /5Phos/GTCAAGAACCGGACAGAACCGGAC 216 GTCCTACAGCGTCCTACAGC 984 /5Phos/TTCGGTCCTACAGCGTCCTACAGC 1752 /5Phos/GTCAGCTGTAGGACGCTGTAGGAC 217 GTCGGATTAAGTCGGATTAA 985 /5Phos/TTCGGTCGGATTAAGTCGGATTAA 1753 /5Phos/GTCATTAATCCGACTTAATCCGAC 218 GTGAACAGAAGTGAACAGAA 986 /5Phos/TTCGGTGAACAGAAGTGAACAGAA 1754 /5Phos/GTCATTCTGTTCACTTCTGTTCAC 219 GTGCCTACACGTGCCTACAC 987 /5Phos/TTCGGTGCCTACACGTGCCTACAC 1755 /5Phos/GTCAGTGTAGGCACGTGTAGGCAC 220 GTGTATCGGAGTGTATCGGA 988 /5Phos/TTCGGTGTATCGGAGTGTATCGGA 1756 /5Phos/GTCATCCGATACACTCCGATACAC 221 GTGTCCATGAGTGTCCATGA 989 /5Phos/TTCGGTGTCCATGAGTGTCCATGA 1757 /5Phos/GTCATCATGGACACTCATGGACAC 222 GTGTCTAATCGTGTCTAATC 990 /5Phos/TTCGGTGTCTAATCGTGTCTAATC 1758 /5Phos/GTCAGATTAGACACGATTAGACAC 223 GTGTTCCTGCGTGTTCCTGC 991 /5Phos/TTCGGTGTTCCTGCGTGTTCCTGC 1759 /5Phos/GTCAGCAGGAACACGCAGGAACAC 224 GTGTTCTGCTGTGTTCTGCT 992 /5Phos/TTCGGTGTTCTGCTGTGTTCTGCT 1760 /5Phos/GTCAAGCAGAACACAGCAGAACAC 225 GTTAAGAGGAGTTAAGAGGA 993 /5Phos/TTCGGTTAAGAGGAGTTAAGAGGA 1761 /5Phos/GTCATCCTCTTAACTCCTCTTAAC 226 GTTAATGCGTGTTAATGCGT 994 /5Phos/TTCGGTTAATGCGTGTTAATGCGT 1762 /5Phos/GTCAACGCATTAACACGCATTAAC 227 GTTAGGCTGTGTTAGGCTGT 995 /5Phos/TTCGGTTAGGCTGTGTTAGGCTGT 1763 /5Phos/GTCAACAGCCTAACACAGCCTAAC 228 GTTCATTGGAGTTCATTGGA 996 /5Phos/TTCGGTTCATTGGAGTTCATTGGA 1764 /5Phos/GTCATCCAATGAACTCCAATGAAC 229 GTTCGGACCAGTTCGGACCA 997 /5Phos/TTCGGTTCGGACCAGTTCGGACCA 1765 /5Phos/GTCATGGTCCGAACTGGTCCGAAC 230 GTTGGCCAGTGTTGGCCAGT 998 /5Phos/TTCGGTTGGCCAGTGTTGGCCAGT 1766 /5Phos/GTCAACTGGCCAACACTGGCCAAC 231 GTTGGTAGTTGTTGGTAGTT 999 /5Phos/TTCGGTTGGTAGTTGTTGGTAGTT 1767 /5Phos/GTCAAACTACCAACAACTACCAAC 232 TAACACGACATAACACGACA 1000 /5Phos/TTCGTAACACGACATAACACGACA 1768 /5Phos/GTCATGTCGTGTTATGTCGTGTTA 233 TAAGAGAGCATAAGAGAGCA 1001 /5Phos/TTCGTAAGAGAGCATAAGAGAGCA 1769 /5Phos/GTCATGCTCTCTTATGCTCTCTTA 234 TAAGAGGCGGTAAGAGGCGG 1002 /5Phos/TTCGTAAGAGGCGGTAAGAGGCGG 1770 /5Phos/GTCACCGCCTCTTACCGCCTCTTA 235 TAAGGAATGGTAAGGAATGG 1003 /5Phos/TTCGTAAGGAATGGTAAGGAATGG 1771 /5Phos/GTCACCATTCCTTACCATTCCTTA 236 TAATGAGCACTAATGAGCAC 1004 /5Phos/TTCGTAATGAGCACTAATGAGCAC 1772 /5Phos/GTCAGTGCTCATTAGTGCTCATTA 237 TACACTGGTCTACACTGGTC 1005 /5Phos/TTCGTACACTGGTCTACACTGGTC 1773 /5Phos/GTCAGACCAGTGTAGACCAGTGTA 238 TACAGCGCAATACAGCGCAA 1006 /5Phos/TTCGTACAGCGCAATACAGCGCAA 1774 /5Phos/GTCATTGCGCTGTATTGCGCTGTA 239 TACAGGTTAGTACAGGTTAG 1007 /5Phos/TTCGTACAGGTTAGTACAGGTTAG 1775 /5Phos/GTCACTAACCTGTACTAACCTGTA 240 TACATTACCGTACATTACCG 1008 /5Phos/TTCGTACATTACCGTACATTACCG 1776 /5Phos/GTCACGGTAATGTACGGTAATGTA 241 TACCAATCTCTACCAATCTC 1009 /5Phos/TTCGTACCAATCTCTACCAATCTC 1777 /5Phos/GTCAGAGATTGGTAGAGATTGGTA 242 TACCGGAGAGTACCGGAGAG 1010 /5Phos/TTCGTACCGGAGAGTACCGGAGAG 1778 /5Phos/GTCACTCTCCGGTACTCTCCGGTA 243 TACCGGCTTCTACCGGCTTC 1011 /5Phos/TTCGTACCGGCTTCTACCGGCTTC 1779 /5Phos/GTCAGAAGCCGGTAGAAGCCGGTA 244 TACCTACATGTACCTACATG 1012 /5Phos/TTCGTACCTACATGTACCTACATG 1780 /5Phos/GTCACATGTAGGTACATGTAGGTA 245 TACGATTACGTACGATTACG 1013 /5Phos/TTCGTACGATTACGTACGATTACG 1781 /5Phos/GTCACGTAATCGTACGTAATCGTA 246 TACGCAGAGGTACGCAGAGG 1014 /5Phos/TTCGTACGCAGAGGTACGCAGAGG 1782 /5Phos/GTCACCTCTGCGTACCTCTGCGTA 247 TACTCAACGATACTCAACGA 1015 /5Phos/TTCGTACTCAACGATACTCAACGA 1783 /5Phos/GTCATCGTTGAGTATCGTTGAGTA 248 TAGACCAACCTAGACCAACC 1016 /5Phos/TTCGTAGACCAACCTAGACCAACC 1784 /5Phos/GTCAGGTTGGTCTAGGTTGGTCTA 249 TAGACCTCCGTAGACCTCCG 1017 /5Phos/TTCGTAGACCTCCGTAGACCTCCG 1785 /5Phos/GTCACGGAGGTCTACGGAGGTCTA 250 TAGCAGTTGATAGCAGTTGA 1018 /5Phos/TTCGTAGCAGTTGATAGCAGTTGA 1786 /5Phos/GTCATCAACTGCTATCAACTGCTA 251 TAGCGCAAGCTAGCGCAAGC 1019 /5Phos/TTCGTAGCGCAAGCTAGCGCAAGC 1787 /5Phos/GTCAGCTTGCGCTAGCTTGCGCTA 252 TAGCTATACCTAGCTATACC 1020 /5Phos/TTCGTAGCTATACCTAGCTATACC 1788 /5Phos/GTCAGGTATAGCTAGGTATAGCTA 253 TAGCTTGCGCTAGCTTGCGC 1021 /5Phos/TTCGTAGCTTGCGCTAGCTTGCGC 1789 /5Phos/GTCAGCGCAAGCTAGCGCAAGCTA 254 TAGGAATCCATAGGAATCCA 1022 /5Phos/TTCGTAGGAATCCATAGGAATCCA 1790 /5Phos/GTCATGGATTCCTATGGATTCCTA 255 TAGGCCGTTCTAGGCCGTTC 1023 /5Phos/TTCGTAGGCCGTTCTAGGCCGTTC 1791 /5Phos/GTCAGAACGGCCTAGAACGGCCTA 256 TAGGTCACTATAGGTCACTA 1024 /5Phos/TTCGTAGGTCACTATAGGTCACTA 1792 /5Phos/GTCATAGTGACCTATAGTGACCTA 257 TAGTCGCGTCTAGTCGCGTC 1025 /5Phos/TTCGTAGTCGCGTCTAGTCGCGTC 1793 /5Phos/GTCAGACGCGACTAGACGCGACTA 258 TATACGGCTATATACGGCTA 1026 /5Phos/TTCGTATACGGCTATATACGGCTA 1794 /5Phos/GTCATAGCCGTATATAGCCGTATA 259 TATCGCGGCATATCGCGGCA 1027 /5Phos/TTCGTATCGCGGCATATCGCGGCA 1795 /5Phos/GTCATGCCGCGATATGCCGCGATA 260 TATGGAGCAATATGGAGCAA 1028 /5Phos/TTCGTATGGAGCAATATGGAGCAA 1796 /5Phos/GTCATTGCTCCATATTGCTCCATA 261 TATGGCGTGGTATGGCGTGG 1029 /5Phos/TTCGTATGGCGTGGTATGGCGTGG 1797 /5Phos/GTCACCACGCCATACCACGCCATA 262 TATGTTCAGGTATGTTCAGG 1030 /5Phos/TTCGTATGTTCAGGTATGTTCAGG 1798 /5Phos/GTCACCTGAACATACCTGAACATA 263 TATTCCTGTCTATTCCTGTC 1031 /5Phos/TTCGTATTCCTGTCTATTCCTGTC 1799 /5Phos/GTCAGACAGGAATAGACAGGAATA 264 TCAAGAGATCTCAAGAGATC 1032 /5Phos/TTCGTCAAGAGATCTCAAGAGATC 1800 /5Phos/GTCAGATCTCTTGAGATCTCTTGA 265 TCACTACCAATCACTACCAA 1033 /5Phos/TTCGTCACTACCAATCACTACCAA 1801 /5Phos/GTCATTGGTAGTGATTGGTAGTGA 266 TCAGTCTGCGTCAGTCTGCG 1034 /5Phos/TTCGTCAGTCTGCGTCAGTCTGCG 1802 /5Phos/GTCACGCAGACTGACGCAGACTGA 267 TCAGTTAAGCTCAGTTAAGC 1035 /5Phos/TTCGTCAGTTAAGCTCAGTTAAGC 1803 /5Phos/GTCAGCTTAACTGAGCTTAACTGA 268 TCCAGAGTGGTCCAGAGTGG 1036 /5Phos/TTCGTCCAGAGTGGTCCAGAGTGG 1804 /5Phos/GTCACCACTCTGGACCACTCTGGA 269 TCCAGTCGTCTCCAGTCGTC 1037 /5Phos/TTCGTCCAGTCGTCTCCAGTCGTC 1805 /5Phos/GTCAGACGACTGGAGACGACTGGA 270 TCCGACGTTGTCCGACGTTG 1038 /5Phos/TTCGTCCGACGTTGTCCGACGTTG 1806 /5Phos/GTCACAACGTCGGACAACGTCGGA 271 TCCTACCGACTCCTACCGAC 1039 /5Phos/TTCGTCCTACCGACTCCTACCGAC 1807 /5Phos/GTCAGTCGGTAGGAGTCGGTAGGA 272 TCCTTCCTCCTCCTTCCTCC 1040 /5Phos/TTCGTCCTTCCTCCTCCTTCCTCC 1808 /5Phos/GTCAGGAGGAAGGAGGAGGAAGGA 273 TCGAGAGCCATCGAGAGCCA 1041 /5Phos/TTCGTCGAGAGCCATCGAGAGCCA 1809 /5Phos/GTCATGGCTCTCGATGGCTCTCGA 274 TCGCACAGACTCGCACAGAC 1042 /5Phos/TTCGTCGCACAGACTCGCACAGAC 1810 /5Phos/GTCAGTCTGTGCGAGTCTGTGCGA 275 TCGCCGTTAGTCGCCGTTAG 1043 /5Phos/TTCGTCGCCGTTAGTCGCCGTTAG 1811 /5Phos/GTCACTAACGGCGACTAACGGCGA 276 TCGGCACAACTCGGCACAAC 1044 /5Phos/TTCGTCGGCACAACTCGGCACAAC 1812 /5Phos/GTCAGTTGTGCCGAGTTGTGCCGA 277 TCGGCAGTTGTCGGCAGTTG 1045 /5Phos/TTCGTCGGCAGTTGTCGGCAGTTG 1813 /5Phos/GTCACAACTGCCGACAACTGCCGA 278 TCGGTCACACTCGGTCACAC 1046 /5Phos/TTCGTCGGTCACACTCGGTCACAC 1814 /5Phos/GTCAGTGTGACCGAGTGTGACCGA 279 TCGTGCTAGCTCGTGCTAGC 1047 /5Phos/TTCGTCGTGCTAGCTCGTGCTAGC 1815 /5Phos/GTCAGCTAGCACGAGCTAGCACGA 280 TCTAGCCTAATCTAGCCTAA 1048 /5Phos/TTCGTCTAGCCTAATCTAGCCTAA 1816 /5Phos/GTCATTAGGCTAGATTAGGCTAGA 281 TCTCACTGCGTCTCACTGCG 1049 /5Phos/TTCGTCTCACTGCGTCTCACTGCG 1817 /5Phos/GTCACGCAGTGAGACGCAGTGAGA 282 TCTCCGGCAATCTCCGGCAA 1050 /5Phos/TTCGTCTCCGGCAATCTCCGGCAA 1818 /5Phos/GTCATTGCCGGAGATTGCCGGAGA 283 TCTCGCTCTCTCTCGCTCTC 1051 /5Phos/TTCGTCTCGCTCTCTCTCGCTCTC 1819 /5Phos/GTCAGAGAGCGAGAGAGAGCGAGA 284 TCTGTCGCAATCTGTCGCAA 1052 /5Phos/TTCGTCTGTCGCAATCTGTCGCAA 1820 /5Phos/GTCATTGCGACAGATTGCGACAGA 285 TCTTAACCTCTCTTAACCTC 1053 /5Phos/TTCGTCTTAACCTCTCTTAACCTC 1821 /5Phos/GTCAGAGGTTAAGAGAGGTTAAGA 286 TGACACATGATGACACATGA 1054 /5Phos/TTCGTGACACATGATGACACATGA 1822 /5Phos/GTCATCATGTGTCATCATGTGTCA 287 TGAGAGTGAATGAGAGTGAA 1055 /5Phos/TTCGTGAGAGTGAATGAGAGTGAA 1823 /5Phos/GTCATTCACTCTCATTCACTCTCA 288 TGAGTGGCTGTGAGTGGCTG 1056 /5Phos/TTCGTGAGTGGCTGTGAGTGGCTG 1824 /5Phos/GTCACAGCCACTCACAGCCACTCA 289 TGATTGACCATGATTGACCA 1057 /5Phos/TTCGTGATTGACCATGATTGACCA 1825 /5Phos/GTCATGGTCAATCATGGTCAATCA 290 TGCAGTCGCATGCAGTCGCA 1058 /5Phos/TTCGTGCAGTCGCATGCAGTCGCA 1826 /5Phos/GTCATGCGACTGCATGCGACTGCA 291 TGCCATGAGGTGCCATGAGG 1059 /5Phos/TTCGTGCCATGAGGTGCCATGAGG 1827 /5Phos/GTCACCTCATGGCACCTCATGGCA 292 TGCCTAACGCTGCCTAACGC 1060 /5Phos/TTCGTGCCTAACGCTGCCTAACGC 1828 /5Phos/GTCAGCGTTAGGCAGCGTTAGGCA 293 TGCCTATAACTGCCTATAAC 1061 /5Phos/TTCGTGCCTATAACTGCCTATAAC 1829 /5Phos/GTCAGTTATAGGCAGTTATAGGCA 294 TGCGAGAGAGTGCGAGAGAG 1062 /5Phos/TTCGTGCGAGAGAGTGCGAGAGAG 1830 /5Phos/GTCACTCTCTCGCACTCTCTCGCA 295 TGCGCGATCATGCGCGATCA 1063 /5Phos/TTCGTGCGCGATCATGCGCGATCA 1831 /5Phos/GTCATGATCGCGCATGATCGCGCA 296 TGCGGAGTGATGCGGAGTGA 1064 /5Phos/TTCGTGCGGAGTGATGCGGAGTGA 1832 /5Phos/GTCATCACTCCGCATCACTCCGCA 297 TGCGGATTCCTGCGGATTCC 1065 /5Phos/TTCGTGCGGATTCCTGCGGATTCC 1833 /5Phos/GTCAGGAATCCGCAGGAATCCGCA 298 TGCGGCTACATGCGGCTACA 1066 /5Phos/TTCGTGCGGCTACATGCGGCTACA 1834 /5Phos/GTCATGTAGCCGCATGTAGCCGCA 299 TGCGTAACAATGCGTAACAA 1067 /5Phos/TTCGTGCGTAACAATGCGTAACAA 1835 /5Phos/GTCATTGTTACGCATTGTTACGCA 300 TGCGTCCTCATGCGTCCTCA 1068 /5Phos/TTCGTGCGTCCTCATGCGTCCTCA 1836 /5Phos/GTCATGAGGACGCATGAGGACGCA 301 TGCGTTCAGCTGCGTTCAGC 1069 /5Phos/TTCGTGCGTTCAGCTGCGTTCAGC 1837 /5Phos/GTCAGCTGAACGCAGCTGAACGCA 302 TGCTTCAGCGTGCTTCAGCG 1070 /5Phos/TTCGTGCTTCAGCGTGCTTCAGCG 1838 /5Phos/GTCACGCTGAAGCACGCTGAAGCA 303 TGCTTGCCTCTGCTTGCCTC 1071 /5Phos/TTCGTGCTTGCCTCTGCTTGCCTC 1839 /5Phos/GTCAGAGGCAAGCAGAGGCAAGCA 204 TGGAACTGGCTGGAACTGGC 1072 /5Phos/TTCGTGGAACTGGCTGGAACTGGC 1840 /5Phos/GTCAGCCAGTTCCAGCCAGTTCCA 305 TGTATTGGAGTGTATTGGAG 1073 /5Phos/TTCGTGTATTGGAGTGTATTGGAG 1841 /5Phos/GTCACTCCAATACACTCCAATACA 306 TGTGGAACGGTGTGGAACGG 1074 /5Phos/TTCGTGTGGAACGGTGTGGAACGG 1842 /5Phos/GTCACCGTTCCACACCGTTCCACA 307 TGTGGAGTCGTGTGGAGTCG 1075 /5Phos/TTCGTGTGGAGTCGTGTGGAGTCG 1843 /5Phos/GTCACGACTCCACACGACTCCACA 308 TGTGTGGCCATGTGTGGCCA 1076 /5Phos/TTCGTGTGTGGCCATGTGTGGCCA 1844 /5Phos/GTCATGGCCACACATGGCCACACA 309 TGTTAAGAGGTGTTAAGAGG 1077 /5Phos/TTCGTGTTAAGAGGTGTTAAGAGG 1845 /5Phos/GTCACCTCTTAACACCTCTTAACA 310 TGTTACTCACTGTTACTCAC 1078 /5Phos/TTCGTGTTACTCACTGTTACTCAC 1846 /5Phos/GTCAGTGAGTAACAGTGAGTAACA 311 TGTTCGCAGCTGTTCGCAGC 1079 /5Phos/TTCGTGTTCGCAGCTGTTCGCAGC 1847 /5Phos/GTCAGCTGCGAACAGCTGCGAACA 312 TGTTGGCATATGTTGGCATA 1080 /5Phos/TTCGTGTTGGCATATGTTGGCATA 1848 /5Phos/GTCATATGCCAACATATGCCAACA 313 TTAAGTGCAGTTAAGTGCAG 1081 /5Phos/TTCGTTAAGTGCAGTTAAGTGCAG 1849 /5Phos/GTCACTGCACTTAACTGCACTTAA 314 TTAGAGATCCTTAGAGATCC 1082 /5Phos/TTCGTTAGAGATCCTTAGAGATCC 1850 /5Phos/GTCAGGATCTCTAAGGATCTCTAA 315 TTAGGTCAGATTAGGTCAGA 1083 /5Phos/TTCGTTAGGTCAGATTAGGTCAGA 1851 /5Phos/GTCATCTGACCTAATCTGACCTAA 316 TTATCTCCTGTTATCTCCTG 1084 /5Phos/TTCGTTATCTCCTGTTATCTCCTG 1852 /5Phos/GTCACAGGAGATAACAGGAGATAA 317 TTCAGTGTCGTTCAGTGTCG 1085 /5Phos/TTCGTTCAGTGTCGTTCAGTGTCG 1853 /5Phos/GTCACGACACTGAACGACACTGAA 318 TTCCAAGAAGTTCCAAGAAG 1086 /5Phos/TTCGTTCCAAGAAGTTCCAAGAAG 1854 /5Phos/GTCACTTCTTGGAACTTCTTGGAA 319 TTCCACCGCATTCCACCGCA 1087 /5Phos/TTCGTTCCACCGCATTCCACCGCA 1855 /5Phos/GTCATGCGGTGGAATGCGGTGGAA 320 TTCCACTATCTTCCACTATC 1088 /5Phos/TTCGTTCCACTATCTTCCACTATC 1856 /5Phos/GTCAGATAGTGGAAGATAGTGGAA 321 TTCCACTTGATTCCACTTGA 1089 /5Phos/TTCGTTCCACTTGATTCCACTTGA 1857 /5Phos/GTCATCAAGTGGAATCAAGTGGAA 322 TTCCGAGAGCTTCCGAGAGC 1090 /5Phos/TTCGTTCCGAGAGCTTCCGAGAGC 1858 /5Phos/GTCAGCTCTCGGAAGCTCTCGGAA 323 TTCCTGAGCCTTCCTGAGCC 1091 /5Phos/TTCGTTCCTGAGCCTTCCTGAGCC 1859 /5Phos/GTCAGGCTCAGGAAGGCTCAGGAA 324 TTCGAGTCGCTTCGAGTCGC 1092 /5Phos/TTCGTTCGAGTCGCTTCGAGTCGC 1860 /5Phos/GTCAGCGACTCGAAGCGACTCGAA 325 TTCGTGCCAGTTCGTGCCAG 1093 /5Phos/TTCGTTCGTGCCAGTTCGTGCCAG 1861 /5Phos/GTCACTGGCACGAACTGGCACGAA 326 TTCTACACCATTCTACACCA 1094 /5Phos/TTCGTTCTACACCATTCTACACCA 1862 /5Phos/GTCATGGTGTAGAATGGTGTAGAA 327 TTCTCGCTCCTTCTCGCTCC 1095 /5Phos/TTCGTTCTCGCTCCTTCTCGCTCC 1863 /5Phos/GTCAGGAGCGAGAAGGAGCGAGAA 328 TTCTGGCCACTTCTGGCCAC 1096 /5Phos/TTCGTTCTGGCCACTTCTGGCCAC 1864 /5Phos/GTCAGTGGCCAGAAGTGGCCAGAA 329 TTGAATGGTGTTGAATGGTG 1097 /5Phos/TTCGTTGAATGGTGTTGAATGGTG 1865 /5Phos/GTCACACCATTCAACACCATTCAA 330 TTGAGCCGACTTGAGCCGAC 1098 /5Phos/TTCGTTGAGCCGACTTGAGCCGAC 1866 /5Phos/GTCAGTCGGCTCAAGTCGGCTCAA 331 TTGCGCCAAGTTGCGCCAAG 1099 /5Phos/TTCGTTGCGCCAAGTTGCGCCAAG 1867 /5Phos/GTCACTTGGCGCAACTTGGCGCAA 332 TTGCTCTTAGTTGCTCTTAG 1100 /5Phos/TTCGTTGCTCTTAGTTGCTCTTAG 1868 /5Phos/GTCACTAAGAGCAACTAAGAGCAA 333 TTGGCAAGGCTTGGCAAGGC 1101 /5Phos/TTCGTTGGCAAGGCTTGGCAAGGC 1869 /5Phos/GTCAGCCTTGCCAAGCCTTGCCAA 334 TTGGCTCACGTTGGCTCACG 1102 /5Phos/TTCGTTGGCTCACGTTGGCTCACG 1870 /5Phos/GTCACGTGAGCCAACGTGAGCCAA 335 TTGGCTTCCATTGGCTTCCA 1103 /5Phos/TTCGTTGGCTTCCATTGGCTTCCA 1871 /5Phos/GTCATGGAAGCCAATGGAAGCCAA 336 TTGTGGATACTTGTGGATAC 1104 /5Phos/TTCGTTGTGGATACTTGTGGATAC 1872 /5Phos/GTCAGTATCCACAAGTATCCACAA 337 AACACGGATGAACACGGATG 1105 /5Phos/TTCGAACACGGATGAACACGGATG 1873 /5Phos/GTCACATCCGTGTTCATCCGTGTT 338 AACAGACCGGAACAGACCGG 1106 /5Phos/TTCGAACAGACCGGAACAGACCGG 1874 /5Phos/GTCACCGGTCTGTTCCGGTCTGTT 339 AACAGTGATCAACAGTGATC 1107 /5Phos/TTCGAACAGTGATCAACAGTGATC 1875 /5Phos/GTCAGATCACTGTTGATCACTGTT 340 AACCATCTTGAACCATCTTG 1108 /5Phos/TTCGAACCATCTTGAACCATCTTG 1876 /5Phos/GTCACAAGATGGTTCAAGATGGTT 341 AACGGTGACGAACGGTGACG 1109 /5Phos/TTCGAACGGTGACGAACGGTGACG 1877 /5Phos/GTCACGTCACCGTTCGTCACCGTT 342 AACTACGCGGAACTACGCGG 1110 /5Phos/TTCGAACTACGCGGAACTACGCGG 1878 /5Phos/GTCACCGCGTAGTTCCGCGTAGTT 343 AACTAGGCTTAACTAGGCTT 1111 /5Phos/TTCGAACTAGGCTTAACTAGGCTT 1879 /5Phos/GTCAAAGCCTAGTTAAGCCTAGTT 344 AACTGGCGTGAACTGGCGTG 1112 /5Phos/TTCGAACTGGCGTGAACTGGCGTG 1880 /5Phos/GTCACACGCCAGTTCACGCCAGTT 345 AAGACAGGATAAGACAGGAT 1113 /5Phos/TTCGAAGACAGGATAAGACAGGAT 1881 /5Phos/GTCAATCCTGTCTTATCCTGTCTT 346 AAGAGCCAGTAAGAGCCAGT 1114 /5Phos/TTCGAAGAGCCAGTAAGAGCCAGT 1882 /5Phos/GTCAACTGGCTCTTACTGGCTCTT 347 AAGAGTATCGAAGAGTATCG 1115 /5Phos/TTCGAAGAGTATCGAAGAGTATCG 1883 /5Phos/GTCACGATACTCTTCGATACTCTT 348 AAGGAACACTAAGGAACACT 1116 /5Phos/TTCGAAGGAACACTAAGGAACACT 1884 /5Phos/GTCAAGTGTTCCTTAGTGTTCCTT 349 AAGTCGCAGGAAGTCGCAGG 1117 /5Phos/TTCGAAGTCGCAGGAAGTCGCAGG 1885 /5Phos/GTCACCTGCGACTTCCTGCGACTT 350 AATCACAGTCAATCACAGTC 1118 /5Phos/TTCGAATCACAGTCAATCACAGTC 1886 /5Phos/GTCAGACTGTGATTGACTGTGATT 351 AATCGCCATTAATCGCCATT 1119 /5Phos/TTCGAATCGCCATTAATCGCCATT 1887 /5Phos/GTCAAATGGCGATTAATGGCGATT 352 AATTGCGGCCAATTGCGGCC 1120 /5Phos/TTCGAATTGCGGCCAATTGCGGCC 1888 /5Phos/GTCAGGCCGCAATTGGCCGCAATT 353 ACAACTCGCGACAACTCGCG 1121 /5Phos/TTCGACAACTCGCGACAACTCGCG 1889 /5Phos/GTCACGCGAGTTGTCGCGAGTTGT 354 ACAAGCTGCGACAAGCTGCG 1122 /5Phos/TTCGACAAGCTGCGACAAGCTGCG 1890 /5Phos/GTCACGCAGCTTGTCGCAGCTTGT 355 ACACCAATTCACACCAATTC 1123 /5Phos/TTCGACACCAATTCACACCAATTC 1891 /5Phos/GTCAGAATTGGTGTGAATTGGTGT 356 ACACGAAGGTACACGAAGGT 1124 /5Phos/TTCGACACGAAGGTACACGAAGGT 1892 /5Phos/GTCAACCTTCGTGTACCTTCGTGT 357 ACAGAATGTGACAGAATGTG 1125 /5Phos/TTCGACAGAATGTGACAGAATGTG 1893 /5Phos/GTCACACATTCTGTCACATTCTGT 358 ACATAGTGGTACATAGTGGT 1126 /5Phos/TTCGACATAGTGGTACATAGTGGT 1894 /5Phos/GTCAACCACTATGTACCACTATGT 359 ACCACCACGTACCACCACGT 1127 /5Phos/TTCGACCACCACGTACCACCACGT 1895 /5Phos/GTCAACGTGGTGGTACGTGGTGGT 360 ACCGACAGCTACCGACAGCT 1128 /5Phos/TTCGACCGACAGCTACCGACAGCT 1896 /5Phos/GTCAAGCTGTCGGTAGCTGTCGGT 361 ACCGGCTAGTACCGGCTAGT 1129 /5Phos/TTCGACCGGCTAGTACCGGCTAGT 1897 /5Phos/GTCAACTAGCCGGTACTAGCCGGT 362 ACCGTAGATTACCGTAGATT 1130 /5Phos/TTCGACCGTAGATTACCGTAGATT 1898 /5Phos/GTCAAATCTACGGTAATCTACGGT 363 ACCGTGACTTACCGTGACTT 1131 /5Phos/TTCGACCGTGACTTACCGTGACTT 1899 /5Phos/GTCAAAGTCACGGTAAGTCACGGT 364 ACCTCACAACACCTCACAAC 1132 /5Phos/TTCGACCTCACAACACCTCACAAC 1900 /5Phos/GTCAGTTGTGAGGTGTTGTGAGGT 365 ACCTTGTCCTACCTTGTCCT 1133 /5Phos/TTCGACCTTGTCCTACCTTGTCCT 1901 /5Phos/GTCAAGGACAAGGTAGGACAAGGT 366 ACGAAGCAGGACGAAGCAGG 1134 /5Phos/TTCGACGAAGCAGGACGAAGCAGG 1902 /5Phos/GTCACCTGCTTCGTCCTGCTTCGT 367 ACGACTGGACACGACTGGAC 1135 /5Phos/TTCGACGACTGGACACGACTGGAC 1903 /5Phos/GTCAGTCCAGTCGTGTCCAGTCGT 368 ACGAGAGCAGACGAGAGCAG 1136 /5Phos/TTCGACGAGAGCAGACGAGAGCAG 1904 /5Phos/GTCACTGCTCTCGTCTGCTCTCGT 369 ACGCCTGTTGACGCCTGTTG 1137 /5Phos/TTCGACGCCTGTTGACGCCTGTTG 1905 /5Phos/GTCACAACAGGCGTCAACAGGCGT 370 ACGCGACTTCACGCGACTTC 1138 /5Phos/TTCGACGCGACTTCACGCGACTTC 1906 /5Phos/GTCAGAAGTCGCGTGAAGTCGCGT 371 ACGGATTGATACGGATTGAT 1139 /5Phos/TTCGACGGATTGATACGGATTGAT 1907 /5Phos/GTCAATCAATCCGTATCAATCCGT 372 ACGGCTCATGACGGCTCATG 1140 /5Phos/TTCGACGGCTCATGACGGCTCATG 1908 /5Phos/GTCACATGAGCCGTCATGAGCCGT 373 ACGGTAAGATACGGTAAGAT 1141 /5Phos/TTCGACGGTAAGATACGGTAAGAT 1909 /5Phos/GTCAATCTTACCGTATCTTACCGT 374 ACGGTAGCACACGGTAGCAC 1142 /5Phos/TTCGACGGTAGCACACGGTAGCAC 1910 /5Phos/GTCAGTGCTACCGTGTGCTACCGT 375 ACGGTGTTCGACGGTGTTCG 1143 /5Phos/TTCGACGGTGTTCGACGGTGTTCG 1911 /5Phos/GTCACGAACACCGTCGAACACCGT 376 ACGTCGATGGACGTCGATGG 1144 /5Phos/TTCGACGTCGATGGACGTCGATGG 1912 /5Phos/GTCACCATCGACGTCCATCGACGT 377 ACGTGCAGACACGTGCAGAC 1145 /5Phos/TTCGACGTGCAGACACGTGCAGAC 1913 /5Phos/GTCAGTCTGCACGTGTCTGCACGT 378 ACGTTCCAGCACGTTCCAGC 1146 /5Phos/TTCGACGTTCCAGCACGTTCCAGC 1914 /5Phos/GTCAGCTGGAACGTGCTGGAACGT 379 ACTAGCTTGTACTAGCTTGT 1147 /5Phos/TTCGACTAGCTTGTACTAGCTTGT 1915 /5Phos/GTCAACAAGCTAGTACAAGCTAGT 380 ACTAGGACGCACTAGGACGC 1148 /5Phos/TTCGACTAGGACGCACTAGGACGC 1916 /5Phos/GTCAGCGTCCTAGTGCGTCCTAGT 381 ACTCACCTGGACTCACCTGG 1149 /5Phos/TTCGACTCACCTGGACTCACCTGG 1917 /5Phos/GTCACCAGGTGAGTCCAGGTGAGT 382 ACTCATATCGACTCATATCG 1150 /5Phos/TTCGACTCATATCGACTCATATCG 1918 /5Phos/GTCACGATATGAGTCGATATGAGT 383 ACTGACCGTGACTGACCGTG 1151 /5Phos/TTCGACTGACCGTGACTGACCGTG 1919 /5Phos/GTCACACGGTCAGTCACGGTCAGT 384 ACTTCTAACCACTTCTAACC 1152 /5Phos/TTCGACTTCTAACCACTTCTAACC 1920 /5Phos/GTCAGGTTAGAAGTGGTTAGAAGT 385 ACTTGGCGCTACTTGGCGCT 1153 /5Phos/TGACACTTGGCGCTACTTGGCGCT 1921 /5Phos/GGGAAGCGCCAAGTAGCGCCAAGT 386 AGAACGCTCCAGAACGCTCC 1154 /5Phos/TGACAGAACGCTCCAGAACGCTCC 1922 /5Phos/GGGAGGAGCGTTCTGGAGCGTTCT 387 AGAACTTAGGAGAACTTAGG 1155 /5Phos/TGACAGAACTTAGGAGAACTTAGG 1923 /5Phos/GGGACCTAAGTTCTCCTAAGTTCT 388 AGAAGCGCATAGAAGCGCAT 1156 /5Phos/TGACAGAAGCGCATAGAAGCGCAT 1924 /5Phos/GGGAATGCGCTTCTATGCGCTTCT 389 AGACAATAGCAGACAATAGC 1157 /5Phos/TGACAGACAATAGCAGACAATAGC 1925 /5Phos/GGGAGCTATTGTCTGCTATTGTCT 390 AGACCGAGACAGACCGAGAC 1158 /5Phos/TGACAGACCGAGACAGACCGAGAC 1926 /5Phos/GGGAGTCTCGGTCTGTCTCGGTCT 391 AGACGCTGTCAGACGCTGTC 1159 /5Phos/TGACAGACGCTGTCAGACGCTGTC 1927 /5Phos/GGGAGACAGCGTCTGACAGCGTCT 392 AGACGTAGCGAGACGTAGCG 1160 /5Phos/TGACAGACGTAGCGAGACGTAGCG 1928 /5Phos/GGGACGCTACGTCTCGCTACGTCT 393 AGAGAGCTCTAGAGAGCTCT 1161 /5Phos/TGACAGAGAGCTCTAGAGAGCTCT 1929 /5Phos/GGGAAGAGCTCTCTAGAGCTCTCT 394 AGAGGCCACTAGAGGCCACT 1162 /5Phos/TGACAGAGGCCACTAGAGGCCACT 1930 /5Phos/GGGAAGTGGCCTCTAGTGGCCTCT 395 AGATTGCCGCAGATTGCCGC 1163 /5Phos/TGACAGATTGCCGCAGATTGCCGC 1931 /5Phos/GGGAGCGGCAATCTGCGGCAATCT 396 AGCACGATGCAGCACGATGC 1164 /5Phos/TGACAGCACGATGCAGCACGATGC 1932 /5Phos/GGGAGCATCGTGCTGCATCGTGCT 397 AGCAGAGAATAGCAGAGAAT 1165 /5Phos/TGACAGCAGAGAATAGCAGAGAAT 1933 /5Phos/GGGAATTCTCTGCTATTCTCTGCT 398 AGCCACAAGGAGCCACAAGG 1166 /5Phos/TGACAGCCACAAGGAGCCACAAGG 1934 /5Phos/GGGACCTTGTGGCTCCTTGTGGCT 399 AGCCAGGAAGAGCCAGGAAG 1167 /5Phos/TGACAGCCAGGAAGAGCCAGGAAG 1935 /5Phos/GGGACTTCCTGGCTCTTCCTGGCT 400 AGCTCTGGAGAGCTCTGGAG 1168 /5Phos/TGACAGCTCTGGAGAGCTCTGGAG 1936 /5Phos/GGGACTCCAGAGCTCTCCAGAGCT 401 AGCTTGGCAGAGCTTGGCAG 1169 /5Phos/TGACAGCTTGGCAGAGCTTGGCAG 1937 /5Phos/GGGACTGCCAAGCTCTGCCAAGCT 402 AGGAATAACGAGGAATAACG 1170 /5Phos/TGACAGGAATAACGAGGAATAACG 1938 /5Phos/GGGACGTTATTCCTCGTTATTCCT 403 AGGAATTGACAGGAATTGAC 1171 /5Phos/TGACAGGAATTGACAGGAATTGAC 1939 /5Phos/GGGAGTCAATTCCTGTCAATTCCT 404 AGGAGGAATTAGGAGGAATT 1172 /5Phos/TGACAGGAGGAATTAGGAGGAATT 1940 /5Phos/GGGAAATTCCTCCTAATTCCTCCT 405 AGGATAGGCCAGGATAGGCC 1173 /5Phos/TGACAGGATAGGCCAGGATAGGCC 1941 /5Phos/GGGAGGCCTATCCTGGCCTATCCT 406 AGGTGGCCTTAGGTGGCCTT 1174 /5Phos/TGACAGGTGGCCTTAGGTGGCCTT 1942 /5Phos/GGGAAAGGCCACCTAAGGCCACCT 407 AGGTGTTGCGAGGTGTTGCG 1175 /5Phos/TGACAGGTGTTGCGAGGTGTTGCG 1943 /5Phos/GGGACGCAACACCTCGCAACACCT 408 AGGTTAGGTGAGGTTAGGTG 1176 /5Phos/TGACAGGTTAGGTGAGGTTAGGTG 1944 /5Phos/GGGACACCTAACCTCACCTAACCT 409 AGTCCGTCCTAGTCCGTCCT 1177 /5Phos/TGACAGTCCGTCCTAGTCCGTCCT 1945 /5Phos/GGGAAGGACGGACTAGGACGGACT 410 AGTCGATCCGAGTCGATCCG 1178 /5Phos/TGACAGTCGATCCGAGTCGATCCG 1946 /5Phos/GGGACGGATCGACTCGGATCGACT 411 AGTCGCTGCTAGTCGCTGCT 1179 /5Phos/TGACAGTCGCTGCTAGTCGCTGCT 1947 /5Phos/GGGAAGCAGCGACTAGCAGCGACT 412 AGTCGTCCTCAGTCGTCCTC 1180 /5Phos/TGACAGTCGTCCTCAGTCGTCCTC 1948 /5Phos/GGGAGAGGACGACTGAGGACGACT 413 AGTGTTCCGTAGTGTTCCGT 1181 /5Phos/TGACAGTGTTCCGTAGTGTTCCGT 1949 /5Phos/GGGAACGGAACACTACGGAACACT 414 AGTTGCTCATAGTTGCTCAT 1182 /5Phos/TGACAGTTGCTCATAGTTGCTCAT 1950 /5Phos/GGGAATGAGCAACTATGAGCAACT 415 ATAACGTGAGATAACGTGAG 1183 /5Phos/TGACATAACGTGAGATAACGTGAG 1951 /5Phos/GGGACTCACGTTATCTCACGTTAT 416 ATACGCAGGCATACGCAGGC 1184 /5Phos/TGACATACGCAGGCATACGCAGGC 1952 /5Phos/GGGAGCCTGCGTATGCCTGCGTAT 417 ATACTGATGCATACTGATGC 1185 /5Phos/TGACATACTGATGCATACTGATGC 1953 /5Phos/GGGAGCATCAGTATGCATCAGTAT 418 ATAGTTCGTCATAGTTCGTC 1186 /5Phos/TGACATAGTTCGTCATAGTTCGTC 1954 /5Phos/GGGAGACGAACTATGACGAACTAT 419 ATATCTTCGCATATCTTCGC 1187 /5Phos/TGACATATCTTCGCATATCTTCGC 1955 /5Phos/GGGAGCGAAGATATGCGAAGATAT 420 ATATGCCTTCATATGCCTTC 1188 /5Phos/TGACATATGCCTTCATATGCCTTC 1956 /5Phos/GGGAGAAGGCATATGAAGGCATAT 421 ATCAGATCACATCAGATCAC 1189 /5Phos/TGACATCAGATCACATCAGATCAC 1957 /5Phos/GGGAGTGATCTGATGTGATCTGAT 422 ATCCAATCTGATCCAATCTG 1190 /5Phos/TGACATCCAATCTGATCCAATCTG 1958 /5Phos/GGGACAGATTGGATCAGATTGGAT 423 ATCCACAGCGATCCACAGCG 1191 /5Phos/TGACATCCACAGCGATCCACAGCG 1959 /5Phos/GGGACGCTGTGGATCGCTGTGGAT 424 ATCCGGAACGATCCGGAACG 1192 /5Phos/TGACATCCGGAACGATCCGGAACG 1960 /5Phos/GGGACGTTCCGGATCGTTCCGGAT 425 ATCGGCTTCCATCGGCTTCC 1193 /5Phos/TGACATCGGCTTCCATCGGCTTCC 1961 /5Phos/GGGAGGAAGCCGATGGAAGCCGAT 426 ATCGTCGGAGATCGTCGGAG 1194 /5Phos/TGACATCGTCGGAGATCGTCGGAG 1962 /5Phos/GGGACTCCGACGATCTCCGACGAT 427 ATCTCTCACGATCTCTCACG 1195 /5Phos/TGACATCTCTCACGATCTCTCACG 1963 /5Phos/GGGACGTGAGAGATCGTGAGAGAT 428 ATGCACCTGCATGCACCTGC 1196 /5Phos/TGACATGCACCTGCATGCACCTGC 1964 /5Phos/GGGAGCAGGTGCATGCAGGTGCAT 429 ATGCAGTCGCATGCAGTCGC 1197 /5Phos/TGACATGCAGTCGCATGCAGTCGC 1965 /5Phos/GGGAGCGACTGCATGCGACTGCAT 430 ATGCCGTAGGATGCCGTAGG 1198 /5Phos/TGACATGCCGTAGGATGCCGTAGG 1966 /5Phos/GGGACCTACGGCATCCTACGGCAT 431 ATGCGCGATCATGCGCGATC 1199 /5Phos/TGACATGCGCGATCATGCGCGATC 1967 /5Phos/GGGAGATCGCGCATGATCGCGCAT 432 ATGTGGTGATATGTGGTGAT 1200 /5Phos/TGACATGTGGTGATATGTGGTGAT 1968 /5Phos/GGGAATCACCACATATCACCACAT 433 ATTACGAGCCATTACGAGCC 1201 /5Phos/TGACATTACGAGCCATTACGAGCC 1969 /5Phos/GGGAGGCTCGTAATGGCTCGTAAT 434 ATTCCACGGCATTCCACGGC 1202 /5Phos/TGACATTCCACGGCATTCCACGGC 1970 /5Phos/GGGAGCCGTGGAATGCCGTGGAAT 435 ATTCGGCGTCATTCGGCGTC 1203 /5Phos/TGACATTCGGCGTCATTCGGCGTC 1971 /5Phos/GGGAGACGCCGAATGACGCCGAAT 436 ATTGGAAGCCATTGGAAGCC 1204 /5Phos/TGACATTGGAAGCCATTGGAAGCC 1972 /5Phos/GGGAGGCTTCCAATGGCTTCCAAT 437 ATTGTCGGCCATTGTCGGCC 1205 /5Phos/TGACATTGTCGGCCATTGTCGGCC 1973 /5Phos/GGGAGGCCGACAATGGCCGACAAT 438 CAACCGCTTGCAACCGCTTG 1206 /5Phos/TGACCAACCGCTTGCAACCGCTTG 1974 /5Phos/GGGACAAGCGGTTGCAAGCGGTTG 439 CAACTGGTGGCAACTGGTGG 1207 /5Phos/TGACCAACTGGTGGCAACTGGTGG 1975 /5Phos/GGGACCACCAGTTGCCACCAGTTG 440 CAAGATGGTGCAAGATGGTG 1208 /5Phos/TGACCAAGATGGTGCAAGATGGTG 1976 /5Phos/GGGACACCATCTTGCACCATCTTG 441 CAAGATTCGACAAGATTCGA 1209 /5Phos/TGACCAAGATTCGACAAGATTCGA 1977 /5Phos/GGGATCGAATCTTGTCGAATCTTG 442 CAAGCACGAGCAAGCACGAG 1210 /5Phos/TGACCAAGCACGAGCAAGCACGAG 1978 /5Phos/GGGACTCGTGCTTGCTCGTGCTTG 443 CAAGCCTGTGCAAGCCTGTG 1211 /5Phos/TGACCAAGCCTGTGCAAGCCTGTG 1979 /5Phos/GGGACACAGGCTTGCACAGGCTTG 444 CAAGCTCACGCAAGCTCACG 1212 /5Phos/TGACCAAGCTCACGCAAGCTCACG 1980 /5Phos/GGGACGTGAGCTTGCGTGAGCTTG 445 CAAGGTTGCGCAAGGTTGCG 1213 /5Phos/TGACCAAGGTTGCGCAAGGTTGCG 1981 /5Phos/GGGACGCAACCTTGCGCAACCTTG 446 CAAGTCGACGCAAGTCGACG 1214 /5Phos/TGACCAAGTCGACGCAAGTCGACG 1982 /5Phos/GGGACGTCGACTTGCGTCGACTTG 447 CACCACGAAGCACCACGAAG 1215 /5Phos/TGACCACCACGAAGCACCACGAAG 1983 /5Phos/GGGACTTCGTGGTGCTTCGTGGTG 448 CACCGATATTCACCGATATT 1216 /5Phos/TGACCACCGATATTCACCGATATT 1984 /5Phos/GGGAAATATCGGTGAATATCGGTG 449 CACCGTCGAACACCGTCGAA 1217 /5Phos/TGACCACCGTCGAACACCGTCGAA 1985 /5Phos/GGGATTCGACGGTGTTCGACGGTG 450 CACCGTGACACACCGTGACA 1218 /5Phos/TGACCACCGTGACACACCGTGACA 1986 /5Phos/GGGATGTCACGGTGTGTCACGGTG 451 CACCTGCTGACACCTGCTGA 1219 /5Phos/TGACCACCTGCTGACACCTGCTGA 1987 /5Phos/GGGATCAGCAGGTGTCAGCAGGTG 452 CACGCACATACACGCACATA 1220 /5Phos/TGACCACGCACATACACGCACATA 1988 /5Phos/GGGATATGTGCGTGTATGTGCGTG 453 CACGCTAAGGCACGCTAAGG 1221 /5Phos/TGACCACGCTAAGGCACGCTAAGG 1989 /5Phos/GGGACCTTAGCGTGCCTTAGCGTG 454 CACGTAATCTCACGTAATCT 1222 /5Phos/TGACCACGTAATCTCACGTAATCT 1990 /5Phos/GGGAAGATTACGTGAGATTACGTG 455 CACGTGGAGTCACGTGGAGT 1223 /5Phos/TGACCACGTGGAGTCACGTGGAGT 1991 /5Phos/GGGAACTCCACGTGACTCCACGTG 456 CACTCGAGAGCACTCGAGAG 1224 /5Phos/TGACCACTCGAGAGCACTCGAGAG 1992 /5Phos/GGGACTCTCGAGTGCTCTCGAGTG 457 CACTCTCTGACACTCTCTGA 1225 /5Phos/TGACCACTCTCTGACACTCTCTGA 1993 /5Phos/GGGATCAGAGAGTGTCAGAGAGTG 458 CACTCTGGCTCACTCTGGCT 1226 /5Phos/TGACCACTCTGGCTCACTCTGGCT 1994 /5Phos/GGGAAGCCAGAGTGAGCCAGAGTG 459 CACTGCCATGCACTGCCATG 1227 /5Phos/TGACCACTGCCATGCACTGCCATG 1995 /5Phos/GGGACATGGCAGTGCATGGCAGTG 460 CACTTGAACTCACTTGAACT 1228 /5Phos/TGACCACTTGAACTCACTTGAACT 1996 /5Phos/GGGAAGTTCAAGTGAGTTCAAGTG 461 CAGACCTGAGCAGACCTGAG 1229 /5Phos/TGACCAGACCTGAGCAGACCTGAG 1997 /5Phos/GGGACTCAGGTCTGCTCAGGTCTG 462 CAGCGAGCATCAGCGAGCAT 1230 /5Phos/TGACCAGCGAGCATCAGCGAGCAT 1998 /5Phos/GGGAATGCTCGCTGATGCTCGCTG 463 CAGGAAGAGGCAGGAAGAGG 1231 /5Phos/TGACCAGGAAGAGGCAGGAAGAGG 1999 /5Phos/GGGACCTCTTCCTGCCTCTTCCTG 464 CAGTCTCATACAGTCTCATA 1232 /5Phos/TGACCAGTCTCATACAGTCTCATA 2000 /5Phos/GGGATATGAGACTGTATGAGACTG 465 CAGTTATCGACAGTTATCGA 1233 /5Phos/TGACCAGTTATCGACAGTTATCGA 2001 /5Phos/GGGATCGATAACTGTCGATAACTG 466 CATACACGCGCATACACGCG 1234 /5Phos/TGACCATACACGCGCATACACGCG 2002 /5Phos/GGGACGCGTGTATGCGCGTGTATG 467 CATACCGACGCATACCGACG 1235 /5Phos/TGACCATACCGACGCATACCGACG 2003 /5Phos/GGGACGTCGGTATGCGTCGGTATG 468 CATCAATGGTCATCAATGGT 1236 /5Phos/TGACCATCAATGGTCATCAATGGT 2004 /5Phos/GGGAACCATTGATGACCATTGATG 469 CATGACACCGCATGACACCG 1237 /5Phos/TGACCATGACACCGCATGACACCG 2005 /5Phos/GGGACGGTGTCATGCGGTGTCATG 470 CATGGTTCGGCATGGTTCGG 1238 /5Phos/TGACCATGGTTCGGCATGGTTCGG 2006 /5Phos/GGGACCGAACCATGCCGAACCATG 471 CATTGGAGCGCATTGGAGCG 1239 /5Phos/TGACCATTGGAGCGCATTGGAGCG 2007 /5Phos/GGGACGCTCCAATGCGCTCCAATG 472 CCAACGAGAGCCAACGAGAG 1240 /5Phos/TGACCCAACGAGAGCCAACGAGAG 2008 /5Phos/GGGACTCTCGTTGGCTCTCGTTGG 473 CCAAGACCAGCCAAGACCAG 1241 /5Phos/TGACCCAAGACCAGCCAAGACCAG 2009 /5Phos/GGGACTGGTCTTGGCTGGTCTTGG 474 CCAATCACGGCCAATCACGG 1242 /5Phos/TGACCCAATCACGGCCAATCACGG 2010 /5Phos/GGGACCGTGATTGGCCGTGATTGG 475 CCACCGTTGTCCACCGTTGT 1243 /5Phos/TGACCCACCGTTGTCCACCGTTGT 2011 /5Phos/GGGAACAACGGTGGACAACGGTGG 476 CCAGATCGGACCAGATCGGA 1244 /5Phos/TGACCCAGATCGGACCAGATCGGA 2012 /5Phos/GGGATCCGATCTGGTCCGATCTGG 477 CCGAAGTCAGCCGAAGTCAG 1245 /5Phos/TGACCCGAAGTCAGCCGAAGTCAG 2013 /5Phos/GGGACTGACTTCGGCTGACTTCGG 478 CCGCTGAAGTCCGCTGAAGT 1246 /5Phos/TGACCCGCTGAAGTCCGCTGAAGT 2014 /5Phos/GGGAACTTCAGCGGACTTCAGCGG 479 CCGGACCATACCGGACCATA 1247 /5Phos/TGACCCGGACCATACCGGACCATA 2015 /5Phos/GGGATATGGTCCGGTATGGTCCGG 480 CCGTTCTAGGCCGTTCTAGG 1248 /5Phos/TGACCCGTTCTAGGCCGTTCTAGG 2016 /5Phos/GGGACCTAGAACGGCCTAGAACGG 481 CCTAATGCGGCCTAATGCGG 1249 /5Phos/TGACCCTAATGCGGCCTAATGCGG 2017 /5Phos/GGGACCGCATTAGGCCGCATTAGG 482 CCTATGACGACCTATGACGA 1250 /5Phos/TGACCCTATGACGACCTATGACGA 2018 /5Phos/GGGATCGTCATAGGTCGTCATAGG 483 CCTCACCAGTCCTCACCAGT 1251 /5Phos/TGACCCTCACCAGTCCTCACCAGT 2019 /5Phos/GGGAACTGGTGAGGACTGGTGAGG 484 CCTGAAGACGCCTGAAGACG 1252 /5Phos/TGACCCTGAAGACGCCTGAAGACG 2020 /5Phos/GGGACGTCTTCAGGCGTCTTCAGG 485 CCTGACTCCTCCTGACTCCT 1253 /5Phos/TGACCCTGACTCCTCCTGACTCCT 2021 /5Phos/GGGAAGGAGTCAGGAGGAGTCAGG 486 CGAAGAGTGGCGAAGAGTGG 1254 /5Phos/TGACCGAAGAGTGGCGAAGAGTGG 2022 /5Phos/GGGACCACTCTTCGCCACTCTTCG 487 CGAAGGTGGTCGAAGGTGGT 1255 /5Phos/TGACCGAAGGTGGTCGAAGGTGGT 2023 /5Phos/GGGAACCACCTTCGACCACCTTCG 488 CGACTAGCAGCGACTAGCAG 1256 /5Phos/TGACCGACTAGCAGCGACTAGCAG 2024 /5Phos/GGGACTGCTAGTCGCTGCTAGTCG 489 CGACTCGAGACGACTCGAGA 1257 /5Phos/TGACCGACTCGAGACGACTCGAGA 2025 /5Phos/GGGATCTCGAGTCGTCTCGAGTCG 490 CGACTTACAACGACTTACAA 1258 /5Phos/TGACCGACTTACAACGACTTACAA 2026 /5Phos/GGGATTGTAAGTCGTTGTAAGTCG 491 CGAGGATTAACGAGGATTAA 1259 /5Phos/TGACCGAGGATTAACGAGGATTAA 2027 /5Phos/GGGATTAATCCTCGTTAATCCTCG 492 CGAGGCATGTCGAGGCATGT 1260 /5Phos/TGACCGAGGCATGTCGAGGCATGT 2028 /5Phos/GGGAACATGCCTCGACATGCCTCG 493 CGAGTCTGCTCGAGTCTGCT 1261 /5Phos/TGACCGAGTCTGCTCGAGTCTGCT 2029 /5Phos/GGGAAGCAGACTCGAGCAGACTCG 494 CGAGTGAGCACGAGTGAGCA 1262 /5Phos/TGACCGAGTGAGCACGAGTGAGCA 2030 /5Phos/GGGATGCTCACTCGTGCTCACTCG 495 CGATCGGAAGCGATCGGAAG 1263 /5Phos/TGACCGATCGGAAGCGATCGGAAG 2031 /5Phos/GGGACTTCCGATCGCTTCCGATCG 496 CGATCTACCGCGATCTACCG 1264 /5Phos/TGACCGATCTACCGCGATCTACCG 2032 /5Phos/GGGACGGTAGATCGCGGTAGATCG 497 CGCCAAGCTTCGCCAAGCTT 1265 /5Phos/TGACCGCCAAGCTTCGCCAAGCTT 2033 /5Phos/GGGAAAGCTTGGCGAAGCTTGGCG 498 CGCCAGAATTCGCCAGAATT 1266 /5Phos/TGACCGCCAGAATTCGCCAGAATT 2034 /5Phos/GGGAAATTCTGGCGAATTCTGGCG 499 CGCGAATGGACGCGAATGGA 1267 /5Phos/TGACCGCGAATGGACGCGAATGGA 2035 /5Phos/GGGATCCATTCGCGTCCATTCGCG 500 CGCTCATCCTCGCTCATCCT 1268 /5Phos/TGACCGCTCATCCTCGCTCATCCT 2036 /5Phos/GGGAAGGATGAGCGAGGATGAGCG 501 CGCTCGAATGCGCTCGAATG 1269 /5Phos/TGACCGCTCGAATGCGCTCGAATG 2037 /5Phos/GGGACATTCGAGCGCATTCGAGCG 502 CGCTTACTATCGCTTACTAT 1270 /5Phos/TGACCGCTTACTATCGCTTACTAT 2038 /5Phos/GGGAATAGTAAGCGATAGTAAGCG 503 CGCTTAGCGTCGCTTAGCGT 1271 /5Phos/TGACCGCTTAGCGTCGCTTAGCGT 2039 /5Phos/GGGAACGCTAAGCGACGCTAAGCG 504 CGGACTTAAGCGGACTTAAG 1272 /5Phos/TGACCGGACTTAAGCGGACTTAAG 2040 /5Phos/GGGACTTAAGTCCGCTTAAGTCCG 505 CGGCGAACAACGGCGAACAA 1273 /5Phos/TGACCGGCGAACAACGGCGAACAA 2041 /5Phos/GGGATTGTTCGCCGTTGTTCGCCG 506 CGGCTTGGAACGGCTTGGAA 1274 /5Phos/TGACCGGCTTGGAACGGCTTGGAA 2042 /5Phos/GGGATTCCAAGCCGTTCCAAGCCG 507 CGGTAGTGCTCGGTAGTGCT 1275 /5Phos/TGACCGGTAGTGCTCGGTAGTGCT 2043 /5Phos/GGGAAGCACTACCGAGCACTACCG 508 CGGTTACACACGGTTACACA 1276 /5Phos/TGACCGGTTACACACGGTTACACA 2044 /5Phos/GGGATGTGTAACCGTGTGTAACCG 509 CGTACCGTGTCGTACCGTGT 1277 /5Phos/TGACCGTACCGTGTCGTACCGTGT 2045 /5Phos/GGGAACACGGTACGACACGGTACG 510 CGTAGAGCCACGTAGAGCCA 1278 /5Phos/TGACCGTAGAGCCACGTAGAGCCA 2046 /5Phos/GGGATGGCTCTACGTGGCTCTACG 511 CGTAGGACTGCGTAGGACTG 1279 /5Phos/TGACCGTAGGACTGCGTAGGACTG 2047 /5Phos/GGGACAGTCCTACGCAGTCCTACG 512 CGTATCACAACGTATCACAA 1280 /5Phos/TGACCGTATCACAACGTATCACAA 2048 /5Phos/GGGATTGTGATACGTTGTGATACG 513 CGTGTTGCGACGTGTTGCGA 1281 /5Phos/TGACCGTGTTGCGACGTGTTGCGA 2049 /5Phos/GGGATCGCAACACGTCGCAACACG 514 CGTTGGTCCACGTTGGTCCA 1282 /5Phos/TGACCGTTGGTCCACGTTGGTCCA 2050 /5Phos/GGGATGGACCAACGTGGACCAACG 515 CTACAGCCGACTACAGCCGA 1283 /5Phos/TGACCTACAGCCGACTACAGCCGA 2051 /5Phos/GGGATCGGCTGTAGTCGGCTGTAG 516 CTACGCAAGGCTACGCAAGG 1284 /5Phos/TGACCTACGCAAGGCTACGCAAGG 2052 /5Phos/GGGACCTTGCGTAGCCTTGCGTAG 517 CTACGGTGTGCTACGGTGTG 1285 /5Phos/TGACCTACGGTGTGCTACGGTGTG 2053 /5Phos/GGGACACACCGTAGCACACCGTAG 518 CTACGTTCCTCTACGTTCCT 1286 /5Phos/TGACCTACGTTCCTCTACGTTCCT 2054 /5Phos/GGGAAGGAACGTAGAGGAACGTAG 519 CTAGAGGCAGCTAGAGGCAG 1287 /5Phos/TGACCTAGAGGCAGCTAGAGGCAG 2055 /5Phos/GGGACTGCCTCTAGCTGCCTCTAG 520 CTAGGTCCAGCTAGGTCCAG 1288 /5Phos/TGACCTAGGTCCAGCTAGGTCCAG 2056 /5Phos/GGGACTGGACCTAGCTGGACCTAG 521 CTAGGTCGCTCTAGGTCGCT 1289 /5Phos/TGACCTAGGTCGCTCTAGGTCGCT 2057 /5Phos/GGGAAGCGACCTAGAGCGACCTAG 522 CTATCGCCGTCTATCGCCGT 1290 /5Phos/TGACCTATCGCCGTCTATCGCCGT 2058 /5Phos/GGGAACGGCGATAGACGGCGATAG 523 CTATGGATCTCTATGGATCT 1291 /5Phos/TGACCTATGGATCTCTATGGATCT 2059 /5Phos/GGGAAGATCCATAGAGATCCATAG 524 CTCGCGAGTTCTCGCGAGTT 1292 /5Phos/TGACCTCGCGAGTTCTCGCGAGTT 2060 /5Phos/GGGAAACTCGCGAGAACTCGCGAG 525 CTCGTGGCAACTCGTGGCAA 1293 /5Phos/TGACCTCGTGGCAACTCGTGGCAA 2061 /5Phos/GGGATTGCCACGAGTTGCCACGAG 526 CTCTACAACTCTCTACAACT 1294 /5Phos/TGACCTCTACAACTCTCTACAACT 2062 /5Phos/GGGAAGTTGTAGAGAGTTGTAGAG 527 CTCTATATCGCTCTATATCG 1295 /5Phos/TGACCTCTATATCGCTCTATATCG 2063 /5Phos/GGGACGATATAGAGCGATATAGAG 528 CTCTCCTTCACTCTCCTTCA 1296 /5Phos/TGACCTCTCCTTCACTCTCCTTCA 2064 /5Phos/GGGATGAAGGAGAGTGAAGGAGAG 529 CTCTCTTGCGCTCTCTTGCG 1297 /5Phos/TGACCTCTCTTGCGCTCTCTTGCG 2065 /5Phos/GGGACGCAAGAGAGCGCAAGAGAG 530 CTCTGCGTTGCTCTGCGTTG 1298 /5Phos/TGACCTCTGCGTTGCTCTGCGTTG 2066 /5Phos/GGGACAACGCAGAGCAACGCAGAG 531 CTGAATCCAGCTGAATCCAG 1299 /5Phos/TGACCTGAATCCAGCTGAATCCAG 2067 /5Phos/GGGACTGGATTCAGCTGGATTCAG 532 CTGAGCTTGGCTGAGCTTGG 1300 /5Phos/TGACCTGAGCTTGGCTGAGCTTGG 2068 /5Phos/GGGACCAAGCTCAGCCAAGCTCAG 533 CTGGATCCGACTGGATCCGA 1301 /5Phos/TGACCTGGATCCGACTGGATCCGA 2069 /5Phos/GGGATCGGATCCAGTCGGATCCAG 534 CTGGTCTGATCTGGTCTGAT 1302 /5Phos/TGACCTGGTCTGATCTGGTCTGAT 2070 /5Phos/GGGAATCAGACCAGATCAGACCAG 535 CTGTCCACAGCTGTCCACAG 1303 /5Phos/TGACCTGTCCACAGCTGTCCACAG 2071 /5Phos/GGGACTGTGGACAGCTGTGGACAG 536 CTGTCCTCCTCTGTCCTCCT 1304 /5Phos/TGACCTGTCCTCCTCTGTCCTCCT 2072 /5Phos/GGGAAGGAGGACAGAGGAGGACAG 537 CTGTCGGATGCTGTCGGATG 1305 /5Phos/TGACCTGTCGGATGCTGTCGGATG 2073 /5Phos/GGGACATCCGACAGCATCCGACAG 538 CTTCATCTGACTTCATCTGA 1306 /5Phos/TGACCTTCATCTGACTTCATCTGA 2074 /5Phos/GGGATCAGATGAAGTCAGATGAAG 539 CTTCCTGCGTCTTCCTGCGT 1307 /5Phos/TGACCTTCCTGCGTCTTCCTGCGT 2075 /5Phos/GGGAACGCAGGAAGACGCAGGAAG 540 CTTCGGCTAGCTTCGGCTAG 1308 /5Phos/TGACCTTCGGCTAGCTTCGGCTAG 2076 /5Phos/GGGACTAGCCGAAGCTAGCCGAAG 541 CTTCTTATGGCTTCTTATGG 1309 /5Phos/TGACCTTCTTATGGCTTCTTATGG 2077 /5Phos/GGGACCATAAGAAGCCATAAGAAG 542 CTTCTTGGATCTTCTTGGAT 1310 /5Phos/TGACCTTCTTGGATCTTCTTGGAT 2078 /5Phos/GGGAATCCAAGAAGATCCAAGAAG 543 CTTGCGATGGCTTGCGATGG 1311 /5Phos/TGACCTTGCGATGGCTTGCGATGG 2079 /5Phos/GGGACCATCGCAAGCCATCGCAAG 544 GAACCTCAGCGAACCTCAGC 1312 /5Phos/TGACGAACCTCAGCGAACCTCAGC 2080 /5Phos/GGGAGCTGAGGTTCGCTGAGGTTC 545 GAACGGATTAGAACGGATTA 1313 /5Phos/TGACGAACGGATTAGAACGGATTA 2081 /5Phos/GGGATAATCCGTTCTAATCCGTTC 546 GAACGTCATTGAACGTCATT 1314 /5Phos/TGACGAACGTCATTGAACGTCATT 2082 /5Phos/GGGAAATGACGTTCAATGACGTTC 547 GAACTGATCCGAACTGATCC 1315 /5Phos/TGACGAACTGATCCGAACTGATCC 2083 /5Phos/GGGAGGATCAGTTCGGATCAGTTC 548 GACAGCAGTCGACAGCAGTC 1316 /5Phos/TGACGACAGCAGTCGACAGCAGTC 2084 /5Phos/GGGAGACTGCTGTCGACTGCTGTC 549 GACCGAATGTGACCGAATGT 1317 /5Phos/TGACGACCGAATGTGACCGAATGT 2085 /5Phos/GGGAACATTCGGTCACATTCGGTC 550 GACGCCATCAGACGCCATCA 1318 /5Phos/TGACGACGCCATCAGACGCCATCA 2086 /5Phos/GGGATGATGGCGTCTGATGGCGTC 551 GACGCGATACGACGCGATAC 1319 /5Phos/TGACGACGCGATACGACGCGATAC 2087 /5Phos/GGGAGTATCGCGTCGTATCGCGTC 552 GACGCTGTGAGACGCTGTGA 1320 /5Phos/TGACGACGCTGTGAGACGCTGTGA 2088 /5Phos/GGGATCACAGCGTCTCACAGCGTC 553 GACGGACCTTGACGGACCTT 1321 /5Phos/TGACGACGGACCTTGACGGACCTT 2089 /5Phos/GGGAAAGGTCCGTCAAGGTCCGTC 554 GACGGAGTCTGACGGAGTCT 1322 /5Phos/TGACGACGGAGTCTGACGGAGTCT 2090 /5Phos/GGGAAGACTCCGTCAGACTCCGTC 555 GAGCACAACCGAGCACAACC 1323 /5Phos/TGACGAGCACAACCGAGCACAACC 2091 /5Phos/GGGAGGTTGTGCTCGGTTGTGCTC 556 GAGGAAGACCGAGGAAGACC 1324 /5Phos/TGACGAGGAAGACCGAGGAAGACC 2092 /5Phos/GGGAGGTCTTCCTCGGTCTTCCTC 557 GAGGCACGATGAGGCACGAT 1325 /5Phos/TGACGAGGCACGATGAGGCACGAT 2093 /5Phos/GGGAATCGTGCCTCATCGTGCCTC 558 GAGGTGAAGCGAGGTGAAGC 1326 /5Phos/TGACGAGGTGAAGCGAGGTGAAGC 2094 /5Phos/GGGAGCTTCACCTCGCTTCACCTC 559 GAGTCACACCGAGTCACACC 1327 /5Phos/TGACGAGTCACACCGAGTCACACC 2095 /5Phos/GGGAGGTGTGACTCGGTGTGACTC 560 GAGTCCAGACGAGTCCAGAC 1328 /5Phos/TGACGAGTCCAGACGAGTCCAGAC 2096 /5Phos/GGGAGTCTGGACTCGTCTGGACTC 561 GATAACCTGTGATAACCTGT 1329 /5Phos/TGACGATAACCTGTGATAACCTGT 2097 /5Phos/GGGAACAGGTTATCACAGGTTATC 562 GATCCAAGGCGATCCAAGGC 1330 /5Phos/TGACGATCCAAGGCGATCCAAGGC 2098 /5Phos/GGGAGCCTTGGATCGCCTTGGATC 563 GATCGAGCCAGATCGAGCCA 1331 /5Phos/TGACGATCGAGCCAGATCGAGCCA 2099 /5Phos/GGGATGGCTCGATCTGGCTCGATC 564 GATGGCAATCGATGGCAATC 1332 /5Phos/TGACGATGGCAATCGATGGCAATC 2100 /5Phos/GGGAGATTGCCATCGATTGCCATC 565 GATTACCAACGATTACCAAC 1333 /5Phos/TGACGATTACCAACGATTACCAAC 2101 /5Phos/GGGAGTTGGTAATCGTTGGTAATC 566 GATTCGTCTTGATTCGTCTT 1334 /5Phos/TGACGATTCGTCTTGATTCGTCTT 2102 /5Phos/GGGAAAGACGAATCAAGACGAATC 567 GATTGTTGGAGATTGTTGGA 1335 /5Phos/TGACGATTGTTGGAGATTGTTGGA 2103 /5Phos/GGGATCCAACAATCTCCAACAATC 568 GCAACACGGAGCAACACGGA 1336 /5Phos/TGACGCAACACGGAGCAACACGGA 2104 /5Phos/GGGATCCGTGTTGCTCCGTGTTGC 569 GCAATGGTACGCAATGGTAC 1337 /5Phos/TGACGCAATGGTACGCAATGGTAC 2105 /5Phos/GGGAGTACCATTGCGTACCATTGC 570 GCACCACATTGCACCACATT 1338 /5Phos/TGACGCACCACATTGCACCACATT 2106 /5Phos/GGGAAATGTGGTGCAATGTGGTGC 571 GCAGATTGGCGCAGATTGGC 1339 /5Phos/TGACGCAGATTGGCGCAGATTGGC 2107 /5Phos/GGGAGCCAATCTGCGCCAATCTGC 572 GCAGGATAGCGCAGGATAGC 1340 /5Phos/TGACGCAGGATAGCGCAGGATAGC 2108 /5Phos/GGGAGCTATCCTGCGCTATCCTGC 573 GCATTAATCCGCATTAATCC 1341 /5Phos/TGACGCATTAATCCGCATTAATCC 2109 /5Phos/GGGAGGATTAATGCGGATTAATGC 574 GCCACCATCTGCCACCATCT 1342 /5Phos/TGACGCCACCATCTGCCACCATCT 2110 /5Phos/GGGAAGATGGTGGCAGATGGTGGC 575 GCCAGATACCGCCAGATACC 1343 /5Phos/TGACGCCAGATACCGCCAGATACC 2111 /5Phos/GGGAGGTATCTGGCGGTATCTGGC 576 GCCATAGATAGCCATAGATA 1344 /5Phos/TGACGCCATAGATAGCCATAGATA 2112 /5Phos/GGGATATCTATGGCTATCTATGGC 577 GCCATTGGACGCCATTGGAC 1345 /5Phos/TCCCGCCATTGGACGCCATTGGAC 2113 /5Phos/GTTGGTCCAATGGCGTCCAATGGC 578 GCCGAATCCTGCCGAATCCT 1346 /5Phos/TCCCGCCGAATCCTGCCGAATCCT 2114 /5Phos/GTTGAGGATTCGGCAGGATTCGGC 579 GCCGTGTCTAGCCGTGTCTA 1347 /5Phos/TCCCGCCGTGTCTAGCCGTGTCTA 2115 /5Phos/GTTGTAGACACGGCTAGACACGGC 580 GCCTTATCTCGCCTTATCTC 1348 /5Phos/TCCCGCCTTATCTCGCCTTATCTC 2116 /5Phos/GTTGGAGATAAGGCGAGATAAGGC 581 GCCTTCGCTTGCCTTCGCTT 1349 /5Phos/TCCCGCCTTCGCTTGCCTTCGCTT 2117 /5Phos/GTTGAAGCGAAGGCAAGCGAAGGC 582 GCGAAGTGGTGCGAAGTGGT 1350 /5Phos/TCCCGCGAAGTGGTGCGAAGTGGT 2118 /5Phos/GTTGACCACTTCGCACCACTTCGC 583 GCGAATATCTGCGAATATCT 1351 /5Phos/TCCCGCGAATATCTGCGAATATCT 2119 /5Phos/GTTGAGATATTCGCAGATATTCGC 584 GCGCTGATACGCGCTGATAC 1352 /5Phos/TCCCGCGCTGATACGCGCTGATAC 2120 /5Phos/GTTGGTATCAGCGCGTATCAGCGC 585 GCGGACTTCTGCGGACTTCT 1353 /5Phos/TCCCGCGGACTTCTGCGGACTTCT 2121 /5Phos/GTTGAGAAGTCCGCAGAAGTCCGC 586 GCGGATAAGTGCGGATAAGT 1354 /5Phos/TCCCGCGGATAAGTGCGGATAAGT 2122 /5Phos/GTTGACTTATCCGCACTTATCCGC 587 GCGGTCCATTGCGGTCCATT 1355 /5Phos/TCCCGCGGTCCATTGCGGTCCATT 2123 /5Phos/GTTGAATGGACCGCAATGGACCGC 588 GCTCAGTTAAGCTCAGTTAA 1356 /5Phos/TCCCGCTCAGTTAAGCTCAGTTAA 2124 /5Phos/GTTGTTAACTGAGCTTAACTGAGC 589 GCTCATTCTAGCTCATTCTA 1357 /5Phos/TCCCGCTCATTCTAGCTCATTCTA 2125 /5Phos/GTTGTAGAATGAGCTAGAATGAGC 590 GCTCCTAAGCGCTCCTAAGC 1358 /5Phos/TCCCGCTCCTAAGCGCTCCTAAGC 2126 /5Phos/GTTGGCTTAGGAGCGCTTAGGAGC 591 GCTGGAAGGAGCTGGAAGGA 1359 /5Phos/TCCCGCTGGAAGGAGCTGGAAGGA 2127 /5Phos/GTTGTCCTTCCAGCTCCTTCCAGC 592 GGAACAATGTGGAACAATGT 1360 /5Phos/TCCCGGAACAATGTGGAACAATGT 2128 /5Phos/GTTGACATTGTTCCACATTGTTCC 593 GGAACATCTCGGAACATCTC 1361 /5Phos/TCCCGGAACATCTCGGAACATCTC 2129 /5Phos/GTTGGAGATGTTCCGAGATGTTCC 594 GGAACCAGTAGGAACCAGTA 1362 /5Phos/TCCCGGAACCAGTAGGAACCAGTA 2130 /5Phos/GTTGTACTGGTTCCTACTGGTTCC 595 GGAACGACTTGGAACGACTT 1363 /5Phos/TCCCGGAACGACTTGGAACGACTT 2131 /5Phos/GTTGAAGTCGTTCCAAGTCGTTCC 596 GGAAGATGATGGAAGATGAT 1364 /5Phos/TCCCGGAAGATGATGGAAGATGAT 2132 /5Phos/GTTGATCATCTTCCATCATCTTCC 597 GGAAGGAGACGGAAGGAGAC 1365 /5Phos/TCCCGGAAGGAGACGGAAGGAGAC 2133 /5Phos/GTTGGTCTCCTTCCGTCTCCTTCC 598 GGAAGTGGTAGGAAGTGGTA 1366 /5Phos/TCCCGGAAGTGGTAGGAAGTGGTA 2134 /5Phos/GTTGTACCACTTCCTACCACTTCC 599 GGAATCAGGTGGAATCAGGT 1367 /5Phos/TCCCGGAATCAGGTGGAATCAGGT 2135 /5Phos/GTTGACCTGATTCCACCTGATTCC 600 GGAATGTGTAGGAATGTGTA 1368 /5Phos/TCCCGGAATGTGTAGGAATGTGTA 2136 /5Phos/GTTGTACACATTCCTACACATTCC 601 GGAGATAGGAGGAGATAGGA 1369 /5Phos/TCCCGGAGATAGGAGGAGATAGGA 2137 /5Phos/GTTGTCCTATCTCCTCCTATCTCC 602 GGAGCAATCCGGAGCAATCC 1370 /5Phos/TCCCGGAGCAATCCGGAGCAATCC 2138 /5Phos/GTTGGGATTGCTCCGGATTGCTCC 603 GGAGGACATCGGAGGACATC 1371 /5Phos/TCCCGGAGGACATCGGAGGACATC 2139 /5Phos/GTTGGATGTCCTCCGATGTCCTCC 604 GGCAATAGCCGGCAATAGCC 1372 /5Phos/TCCCGGCAATAGCCGGCAATAGCC 2140 /5Phos/GTTGGGCTATTGCCGGCTATTGCC 605 GGCAGAAGGAGGCAGAAGGA 1373 /5Phos/TCCCGGCAGAAGGAGGCAGAAGGA 2141 /5Phos/GTTGTCCTTCTGCCTCCTTCTGCC 606 GGCAGGAATAGGCAGGAATA 1374 /5Phos/TCCCGGCAGGAATAGGCAGGAATA 2142 /5Phos/GTTGTATTCCTGCCTATTCCTGCC 607 GGCATACACCGGCATACACC 1375 /5Phos/TCCCGGCATACACCGGCATACACC 2143 /5Phos/GTTGGGTGTATGCCGGTGTATGCC 608 GGCCGTTGTAGGCCGTTGTA 1376 /5Phos/TCCCGGCCGTTGTAGGCCGTTGTA 2144 /5Phos/GTTGTACAACGGCCTACAACGGCC 609 GGCCTGCTTAGGCCTGCTTA 1377 /5Phos/TCCCGGCCTGCTTAGGCCTGCTTA 2145 /5Phos/GTTGTAAGCAGGCCTAAGCAGGCC 610 GGCGAGGTAAGGCGAGGTAA 1378 /5Phos/TCCCGGCGAGGTAAGGCGAGGTAA 2146 /5Phos/GTTGTTACCTCGCCTTACCTCGCC 611 GGCGTGACATGGCGTGACAT 1379 /5Phos/TCCCGGCGTGACATGGCGTGACAT 2147 /5Phos/GTTGATGTCACGCCATGTCACGCC 612 GGCTCCAAGAGGCTCCAAGA 1380 /5Phos/TCCCGGCTCCAAGAGGCTCCAAGA 2148 /5Phos/GTTGTCTTGGAGCCTCTTGGAGCC 613 GGCTGCTCAAGGCTGCTCAA 1381 /5Phos/TCCCGGCTGCTCAAGGCTGCTCAA 2149 /5Phos/GTTGTTGAGCAGCCTTGAGCAGCC 614 GGCTGTGCTTGGCTGTGCTT 1382 /5Phos/TCCCGGCTGTGCTTGGCTGTGCTT 2150 /5Phos/GTTGAAGCACAGCCAAGCACAGCC 615 GGCTTCTGTCGGCTTCTGTC 1383 /5Phos/TCCCGGCTTCTGTCGGCTTCTGTC 2151 /5Phos/GTTGGACAGAAGCCGACAGAAGCC 616 GGTATCGCTTGGTATCGCTT 1384 /5Phos/TCCCGGTATCGCTTGGTATCGCTT 2152 /5Phos/GTTGAAGCGATACCAAGCGATACC 617 GGTCCTTCCAGGTCCTTCCA 1385 /5Phos/TCCCGGTCCTTCCAGGTCCTTCCA 2153 /5Phos/GTTGTGGAAGGACCTGGAAGGACC 618 GGTCGGTTATGGTCGGTTAT 1386 /5Phos/TCCCGGTCGGTTATGGTCGGTTAT 2154 /5Phos/GTTGATAACCGACCATAACCGACC 619 GGTCTGACGAGGTCTGACGA 1387 /5Phos/TCCCGGTCTGACGAGGTCTGACGA 2155 /5Phos/GTTGTCGTCAGACCTCGTCAGACC 620 GGTGACCACTGGTGACCACT 1388 /5Phos/TCCCGGTGACCACTGGTGACCACT 2156 /5Phos/GTTGAGTGGTCACCAGTGGTCACC 621 GGTGAGTCCAGGTGAGTCCA 1389 /5Phos/TCCCGGTGAGTCCAGGTGAGTCCA 2157 /5Phos/GTTGTGGACTCACCTGGACTCACC 622 GGTGGCGAATGGTGGCGAAT 1390 /5Phos/TCCCGGTGGCGAATGGTGGCGAAT 2158 /5Phos/GTTGATTCGCCACCATTCGCCACC 623 GGTGTATATCGGTGTATATC 1391 /5Phos/TCCCGGTGTATATCGGTGTATATC 2159 /5Phos/GTTGGATATACACCGATATACACC 624 GGTTCCTTAAGGTTCCTTAA 1392 /5Phos/TCCCGGTTCCTTAAGGTTCCTTAA 2160 /5Phos/GTTGTTAAGGAACCTTAAGGAACC 625 GGTTCTACAAGGTTCTACAA 1393 /5Phos/TCCCGGTTCTACAAGGTTCTACAA 2161 /5Phos/GTTGTTGTAGAACCTTGTAGAACC 626 GGTTGGCGTTGGTTGGCGTT 1394 /5Phos/TCCCGGTTGGCGTTGGTTGGCGTT 2162 /5Phos/GTTGAACGCCAACCAACGCCAACC 627 GTAACACGCTGTAACACGCT 1395 /5Phos/TCCCGTAACACGCTGTAACACGCT 2163 /5Phos/GTTGAGCGTGTTACAGCGTGTTAC 628 GTAGAGCGACGTAGAGCGAC 1396 /5Phos/TCCCGTAGAGCGACGTAGAGCGAC 2164 /5Phos/GTTGGTCGCTCTACGTCGCTCTAC 629 GTAGCTGCTCGTAGCTGCTC 1397 /5Phos/TCCCGTAGCTGCTCGTAGCTGCTC 2165 /5Phos/GTTGGAGCAGCTACGAGCAGCTAC 630 GTAGGTGGATGTAGGTGGAT 1398 /5Phos/TCCCGTAGGTGGATGTAGGTGGAT 2166 /5Phos/GTTGATCCACCTACATCCACCTAC 631 GTAGTCAGCCGTAGTCAGCC 1399 /5Phos/TCCCGTAGTCAGCCGTAGTCAGCC 2167 /5Phos/GTTGGGCTGACTACGGCTGACTAC 632 GTCCTTCCACGTCCTTCCAC 1400 /5Phos/TCCCGTCCTTCCACGTCCTTCCAC 2168 /5Phos/GTTGGTGGAAGGACGTGGAAGGAC 633 GTCGAGCAGTGTCGAGCAGT 1401 /5Phos/TCCCGTCGAGCAGTGTCGAGCAGT 2169 /5Phos/GTTGACTGCTCGACACTGCTCGAC 634 GTCGCACAGAGTCGCACAGA 1402 /5Phos/TCCCGTCGCACAGAGTCGCACAGA 2170 /5Phos/GTTGTCTGTGCGACTCTGTGCGAC 635 GTCGCACTTCGTCGCACTTC 1403 /5Phos/TCCCGTCGCACTTCGTCGCACTTC 2171 /5Phos/GTTGGAAGTGCGACGAAGTGCGAC 636 GTCTGGTGGTGTCTGGTGGT 1404 /5Phos/TCCCGTCTGGTGGTGTCTGGTGGT 2172 /5Phos/GTTGACCACCAGACACCACCAGAC 637 GTGAACTGTTGTGAACTGTT 1405 /5Phos/TCCCGTGAACTGTTGTGAACTGTT 2173 /5Phos/GTTGAACAGTTCACAACAGTTCAC 638 GTGCCATCCTGTGCCATCCT 1406 /5Phos/TCCCGTGCCATCCTGTGCCATCCT 2174 /5Phos/GTTGAGGATGGCACAGGATGGCAC 639 GTGCGTGAACGTGCGTGAAC 1407 /5Phos/TCCCGTGCGTGAACGTGCGTGAAC 2175 /5Phos/GTTGGTTCACGCACGTTCACGCAC 640 GTGGAGATGTGTGGAGATGT 1408 /5Phos/TCCCGTGGAGATGTGTGGAGATGT 2176 /5Phos/GTTGACATCTCCACACATCTCCAC 641 GTGGTGCAACGTGGTGCAAC 1409 /5Phos/TCCCGTGGTGCAACGTGGTGCAAC 2177 /5Phos/GTTGGTTGCACCACGTTGCACCAC 642 GTGTCGTTAAGTGTCGTTAA 1410 /5Phos/TCCCGTGTCGTTAAGTGTCGTTAA 2178 /5Phos/GTTGTTAACGACACTTAACGACAC 643 GTGTCTCAATGTGTCTCAAT 1411 /5Phos/TCCCGTGTCTCAATGTGTCTCAAT 2179 /5Phos/GTTGATTGAGACACATTGAGACAC 644 GTGTGATGACGTGTGATGAC 1412 /5Phos/TCCCGTGTGATGACGTGTGATGAC 2180 /5Phos/GTTGGTCATCACACGTCATCACAC 645 GTTAGATCGCGTTAGATCGC 1413 /5Phos/TCCCGTTAGATCGCGTTAGATCGC 2181 /5Phos/GTTGGCGATCTAACGCGATCTAAC 646 TAAGCCGATATAAGCCGATA 1414 /5Phos/TCCCTAAGCCGATATAAGCCGATA 2182 /5Phos/GTTGTATCGGCTTATATCGGCTTA 647 TAAGGACACCTAAGGACACC 1415 /5Phos/TCCCTAAGGACACCTAAGGACACC 2183 /5Phos/GTTGGGTGTCCTTAGGTGTCCTTA 648 TAAGGCCAAGTAAGGCCAAG 1416 /5Phos/TCCCTAAGGCCAAGTAAGGCCAAG 2184 /5Phos/GTTGCTTGGCCTTACTTGGCCTTA 649 TAATAGCGAGTAATAGCGAG 1417 /5Phos/TCCCTAATAGCGAGTAATAGCGAG 2185 /5Phos/GTTGCTCGCTATTACTCGCTATTA 650 TAATGGCCGGTAATGGCCGG 1418 /5Phos/TCCCTAATGGCCGGTAATGGCCGG 2186 /5Phos/GTTGCCGGCCATTACCGGCCATTA 651 TACCATTGGATACCATTGGA 1419 /5Phos/TCCCTACCATTGGATACCATTGGA 2187 /5Phos/GTTGTCCAATGGTATCCAATGGTA 652 TACGACCACCTACGACCACC 1420 /5Phos/TCCCTACGACCACCTACGACCACC 2188 /5Phos/GTTGGGTGGTCGTAGGTGGTCGTA 653 TACGACCTTATACGACCTTA 1421 /5Phos/TCCCTACGACCTTATACGACCTTA 2189 /5Phos/GTTGTAAGGTCGTATAAGGTCGTA 654 TACGTGATTCTACGTGATTC 1422 /5Phos/TCCCTACGTGATTCTACGTGATTC 2190 /5Phos/GTTGGAATCACGTAGAATCACGTA 655 TACTAGTCAGTACTAGTCAG 1423 /5Phos/TCCCTACTAGTCAGTACTAGTCAG 2191 /5Phos/GTTGCTGACTAGTACTGACTAGTA 656 TACTGACAAGTACTGACAAG 1424 /5Phos/TCCCTACTGACAAGTACTGACAAG 2192 /5Phos/GTTGCTTGTCAGTACTTGTCAGTA 657 TACTGCTGGCTACTGCTGGC 1425 /5Phos/TCCCTACTGCTGGCTACTGCTGGC 2193 /5Phos/GTTGGCCAGCAGTAGCCAGCAGTA 658 TAGACCGTAATAGACCGTAA 1426 /5Phos/TCCCTAGACCGTAATAGACCGTAA 2194 /5Phos/GTTGTTACGGTCTATTACGGTCTA 659 TAGACGAAGATAGACGAAGA 1427 /5Phos/TCCCTAGACGAAGATAGACGAAGA 2195 /5Phos/GTTGTCTTCGTCTATCTTCGTCTA 660 TAGCCTAGCCTAGCCTAGCC 1428 /5Phos/TCCCTAGCCTAGCCTAGCCTAGCC 2196 /5Phos/GTTGGGCTAGGCTAGGCTAGGCTA 661 TAGCGAATTCTAGCGAATTC 1429 /5Phos/TCCCTAGCGAATTCTAGCGAATTC 2197 /5Phos/GTTGGAATTCGCTAGAATTCGCTA 662 TAGCTGCCACTAGCTGCCAC 1430 /5Phos/TCCCTAGCTGCCACTAGCTGCCAC 2198 /5Phos/GTTGGTGGCAGCTAGTGGCAGCTA 663 TAGGTAGGCATAGGTAGGCA 1431 /5Phos/TCCCTAGGTAGGCATAGGTAGGCA 2199 /5Phos/GTTGTGCCTACCTATGCCTACCTA 664 TAGTCGTTACTAGTCGTTAC 1432 /5Phos/TCCCTAGTCGTTACTAGTCGTTAC 2200 /5Phos/GTTGGTAACGACTAGTAACGACTA 665 TAGTGCGAAGTAGTGCGAAG 1433 /5Phos/TCCCTAGTGCGAAGTAGTGCGAAG 2201 /5Phos/GTTGCTTCGCACTACTTCGCACTA 666 TAGTGGACGCTAGTGGACGC 1434 /5Phos/TCCCTAGTGGACGCTAGTGGACGC 2202 /5Phos/GTTGGCGTCCACTAGCGTCCACTA 667 TATAACGGTGTATAACGGTG 1435 /5Phos/TCCCTATAACGGTGTATAACGGTG 2203 /5Phos/GTTGCACCGTTATACACCGTTATA 668 TATAGAACCGTATAGAACCG 1436 /5Phos/TCCCTATAGAACCGTATAGAACCG 2204 /5Phos/GTTGCGGTTCTATACGGTTCTATA 669 TATCCGAAGGTATCCGAAGG 1437 /5Phos/TCCCTATCCGAAGGTATCCGAAGG 2205 /5Phos/GTTGCCTTCGGATACCTTCGGATA 670 TATCGGAGCCTATCGGAGCC 1438 /5Phos/TCCCTATCGGAGCCTATCGGAGCC 2206 /5Phos/GTTGGGCTCCGATAGGCTCCGATA 671 TATCGGCCTGTATCGGCCTG 1439 /5Phos/TCCCTATCGGCCTGTATCGGCCTG 2207 /5Phos/GTTGCAGGCCGATACAGGCCGATA 672 TATCGTCGGCTATCGTCGGC 1440 /5Phos/TCCCTATCGTCGGCTATCGTCGGC 2208 /5Phos/GTTGGCCGACGATAGCCGACGATA 673 TATGCGCCACTATGCGCCAC 1441 /5Phos/TCCCTATGCGCCACTATGCGCCAC 2209 /5Phos/GTTGGTGGCGCATAGTGGCGCATA 674 TATGGCCGTCTATGGCCGTC 1442 /5Phos/TCCCTATGGCCGTCTATGGCCGTC 2210 /5Phos/GTTGGACGGCCATAGACGGCCATA 675 TATTCTTCCGTATTCTTCCG 1443 /5Phos/TCCCTATTCTTCCGTATTCTTCCG 2211 /5Phos/GTTGCGGAAGAATACGGAAGAATA 676 TCAAGCAACGTCAAGCAACG 1444 /5Phos/TCCCTCAAGCAACGTCAAGCAACG 2212 /5Phos/GTTGCGTTGCTTGACGTTGCTTGA 677 TCAAGCAGTCTCAAGCAGTC 1445 /5Phos/TCCCTCAAGCAGTCTCAAGCAGTC 2213 /5Phos/GTTGGACTGCTTGAGACTGCTTGA 678 TCAAGTCCGATCAAGTCCGA 1446 /5Phos/TCCCTCAAGTCCGATCAAGTCCGA 2214 /5Phos/GTTGTCGGACTTGATCGGACTTGA 679 TCAATCGAGATCAATCGAGA 1447 /5Phos/TCCCTCAATCGAGATCAATCGAGA 2215 /5Phos/GTTGTCTCGATTGATCTCGATTGA 680 TCAATGTCGATCAATGTCGA 1448 /5Phos/TCCCTCAATGTCGATCAATGTCGA 2216 /5Phos/GTTGTCGACATTGATCGACATTGA 681 TCACTGAGGCTCACTGAGGC 1449 /5Phos/TCCCTCACTGAGGCTCACTGAGGC 2217 /5Phos/GTTGGCCTCAGTGAGCCTCAGTGA 682 TCAGCGAGACTCAGCGAGAC 1450 /5Phos/TCCCTCAGCGAGACTCAGCGAGAC 2218 /5Phos/GTTGGTCTCGCTGAGTCTCGCTGA 683 TCAGGAGGAATCAGGAGGAA 1451 /5Phos/TCCCTCAGGAGGAATCAGGAGGAA 2219 /5Phos/GTTGTTCCTCCTGATTCCTCCTGA 684 TCAGGCACAGTCAGGCACAG 1452 /5Phos/TCCCTCAGGCACAGTCAGGCACAG 2220 /5Phos/GTTGCTGTGCCTGACTGTGCCTGA 685 TCAGGCTTCCTCAGGCTTCC 1453 /5Phos/TCCCTCAGGCTTCCTCAGGCTTCC 2221 /5Phos/GTTGGGAAGCCTGAGGAAGCCTGA 686 TCCACACTCGTCCACACTCG 1454 /5Phos/TCCCTCCACACTCGTCCACACTCG 2222 /5Phos/GTTGCGAGTGTGGACGAGTGTGGA 687 TCCACAGCGATCCACAGCGA 1455 /5Phos/TCCCTCCACAGCGATCCACAGCGA 2223 /5Phos/GTTGTCGCTGTGGATCGCTGTGGA 688 TCCAGCTGCATCCAGCTGCA 1456 /5Phos/TCCCTCCAGCTGCATCCAGCTGCA 2224 /5Phos/GTTGTGCAGCTGGATGCAGCTGGA 689 TCCATAATCCTCCATAATCC 1457 /5Phos/TCCCTCCATAATCCTCCATAATCC 2225 /5Phos/GTTGGGATTATGGAGGATTATGGA 690 TCCGGACCAATCCGGACCAA 1458 /5Phos/TCCCTCCGGACCAATCCGGACCAA 2226 /5Phos/GTTGTTGGTCCGGATTGGTCCGGA 691 TCCGTAACGGTCCGTAACGG 1459 /5Phos/TCCCTCCGTAACGGTCCGTAACGG 2227 /5Phos/GTTGCCGTTACGGACCGTTACGGA 692 TCCGTAGGTCTCCGTAGGTC 1460 /5Phos/TCCCTCCGTAGGTCTCCGTAGGTC 2228 /5Phos/GTTGGACCTACGGAGACCTACGGA 693 TCCGTCCAAGTCCGTCCAAG 1461 /5Phos/TCCCTCCGTCCAAGTCCGTCCAAG 2229 /5Phos/GTTGCTTGGACGGACTTGGACGGA 694 TCCTGAACCGTCCTGAACCG 1462 /5Phos/TCCCTCCTGAACCGTCCTGAACCG 2230 /5Phos/GTTGCGGTTCAGGACGGTTCAGGA 695 TCCTGGCATGTCCTGGCATG 1463 /5Phos/TCCCTCCTGGCATGTCCTGGCATG 2231 /5Phos/GTTGCATGCCAGGACATGCCAGGA 696 TCGCGCTACATCGCGCTACA 1464 /5Phos/TCCCTCGCGCTACATCGCGCTACA 2232 /5Phos/GTTGTGTAGCGCGATGTAGCGCGA 697 TCGGTTACCATCGGTTACCA 1465 /5Phos/TCCCTCGGTTACCATCGGTTACCA 2233 /5Phos/GTTGTGGTAACCGATGGTAACCGA 698 TCGTCCGTCATCGTCCGTCA 6146 /5Phos/TCCCTCGTCCGTCATCGTCCGTCA 2234 /5Phos/GTTGTGACGGACGATGACGGACGA 699 TCGTCCTCAGTCGTCCTCAG 1467 /5Phos/TCCCTCGTCCTCAGTCGTCCTCAG 2235 /5Phos/GTTGCTGAGGACGACTGAGGACGA 700 TCTACCGCTCTCTACCGCTC 1468 /5Phos/TCCCTCTACCGCTCTCTACCGCTC 2236 /5Phos/GTTGGAGCGGTAGAGAGCGGTAGA 701 TCTAGCTCGGTCTAGCTCGG 1469 /5Phos/TCCCTCTAGCTCGGTCTAGCTCGG 2237 /5Phos/GTTGCCGAGCTAGACCGAGCTAGA 702 TCTCGGCTGATCTCGGCTGA 1470 /5Phos/TCCCTCTCGGCTGATCTCGGCTGA 2238 /5Phos/GTTGTCAGCCGAGATCAGCCGAGA 703 TCTCGGTCAGTCTCGGTCAG 1471 /5Phos/TCCCTCTCGGTCAGTCTCGGTCAG 2239 /5Phos/GTTGCTGACCGAGACTGACCGAGA 704 TCTCTAGATCTCTCTAGATC 1472 /5Phos/TCCCTCTCTAGATCTCTCTAGATC 2240 /5Phos/GTTGGATCTAGAGAGATCTAGAGA 705 TCTGACCGCATCTGACCGCA 1473 /5Phos/TCCCTCTGACCGCATCTGACCGCA 2241 /5Phos/GTTGTGCGGTCAGATGCGGTCAGA 706 TCTGGACAGATCTGGACAGA 1474 /5Phos/TCCCTCTGGACAGATCTGGACAGA 2242 /5Phos/GTTGTCTGTCCAGATCTGTCCAGA 707 TCTGGATAAGTCTGGATAAG 1475 /5Phos/TCCCTCTGGATAAGTCTGGATAAG 2243 /5Phos/GTTGCTTATCCAGACTTATCCAGA 708 TCTTACGGCCTCTTACGGCC 1476 /5Phos/TCCCTCTTACGGCCTCTTACGGCC 2244 /5Phos/GTTGGGCCGTAAGAGGCCGTAAGA 709 TCTTGCATACTCTTGCATAC 1477 /5Phos/TCCCTCTTGCATACTCTTGCATAC 2245 /5Phos/GTTGGTATGCAAGAGTATGCAAGA 710 TGAACTTGGATGAACTTGGA 1478 /5Phos/TCCCTGAACTTGGATGAACTTGGA 2246 /5Phos/GTTGTCCAAGTTCATCCAAGTTCA 711 TGACACAGCGTGACACAGCG 1479 /5Phos/TCCCTGACACAGCGTGACACAGCG 2247 /5Phos/GTTGCGCTGTGTCACGCTGTGTCA 712 TGACAGGTCCTGACAGGTCC 1480 /5Phos/TCCCTGACAGGTCCTGACAGGTCC 2248 /5Phos/GTTGGGACCTGTCAGGACCTGTCA 713 TGACCTTCCGTGACCTTCCG 1481 /5Phos/TCCCTGACCTTCCGTGACCTTCCG 2249 /5Phos/GTTGCGGAAGGTCACGGAAGGTCA 714 TGACGTCGGATGACGTCGGA 1482 /5Phos/TCCCTGACGTCGGATGACGTCGGA 2250 /5Phos/GTTGTCCGACGTCATCCGACGTCA 715 TGACTATCTCTGACTATCTC 1483 /5Phos/TCCCTGACTATCTCTGACTATCTC 2251 /5Phos/GTTGGAGATAGTCAGAGATAGTCA 716 TGACTCCAGGTGACTCCAGG 1484 /5Phos/TCCCTGACTCCAGGTGACTCCAGG 2252 /5Phos/GTTGCCTGGAGTCACCTGGAGTCA 717 TGAGAGCAGGTGAGAGCAGG 1485 /5Phos/TCCCTGAGAGCAGGTGAGAGCAGG 2253 /5Phos/GTTGCCTGCTCTCACCTGCTCTCA 718 TGAGCCTCCATGAGCCTCCA 1486 /5Phos/TCCCTGAGCCTCCATGAGCCTCCA 2254 /5Phos/GTTGTGGAGGCTCATGGAGGCTCA 719 TGAGTATGGATGAGTATGGA 1487 /5Phos/TCCCTGAGTATGGATGAGTATGGA 2255 /5Phos/GTTGTCCATACTCATCCATACTCA 720 TGCAACATACTGCAACATAC 1488 /5Phos/TCCCTGCAACATACTGCAACATAC 2256 /5Phos/GTTGGTATGTTGCAGTATGTTGCA 721 TGCGCTGTAGTGCGCTGTAG 1489 /5Phos/TCCCTGCGCTGTAGTGCGCTGTAG 2257 /5Phos/GTTGCTACAGCGCACTACAGCGCA 722 TGCTAACCGGTGCTAACCGG 1490 /5Phos/TCCCTGCTAACCGGTGCTAACCGG 2258 /5Phos/GTTGCCGGTTAGCACCGGTTAGCA 723 TGCTCCACTGTGCTCCACTG 1491 /5Phos/TCCCTGCTCCACTGTGCTCCACTG 2259 /5Phos/GTTGCAGTGGAGCACAGTGGAGCA 724 TGGAAGGAGCTGGAAGGAGC 1492 /5Phos/TCCCTGGAAGGAGCTGGAAGGAGC 2260 /5Phos/GTTGGCTCCTTCCAGCTCCTTCCA 725 TGGCAGTGACTGGCAGTGAC 1493 /5Phos/TCCCTGGCAGTGACTGGCAGTGAC 2261 /5Phos/GTTGGTCACTGCCAGTCACTGCCA 726 TGGCATCAGCTGGCATCAGC 1494 /5Phos/TCCCTGGCATCAGCTGGCATCAGC 2262 /5Phos/GTTGGCTGATGCCAGCTGATGCCA 727 TGGCCTTATATGGCCTTATA 1495 /5Phos/TCCCTGGCCTTATATGGCCTTATA 2263 /5Phos/GTTGTATAAGGCCATATAAGGCCA 728 TGGCGAAGCATGGCGAAGCA 1496 /5Phos/TCCCTGGCGAAGCATGGCGAAGCA 2264 /5Phos/GTTGTGCTTCGCCATGCTTCGCCA 729 TGGCTTAAGATGGCTTAAGA 1497 /5Phos/TCCCTGGCTTAAGATGGCTTAAGA 2265 /5Phos/GTTGTCTTAAGCCATCTTAAGCCA 730 TGGTCAGCTCTGGTCAGCTC 1498 /5Phos/TCCCTGGTCAGCTCTGGTCAGCTC 2266 /5Phos/GTTGGAGCTGACCAGAGCTGACCA 731 TGGTTCCAACTGGTTCCAAC 1499 /5Phos/TCCCTGGTTCCAACTGGTTCCAAC 2267 /5Phos/GTTGGTTGGAACCAGTTGGAACCA 732 TGGTTGGTAATGGTTGGTAA 1500 /5Phos/TCCCTGGTTGGTAATGGTTGGTAA 2268 /5Phos/GTTGTTACCAACCATTACCAACCA 733 TGTACGCGCATGTACGCGCA 1501 /5Phos/TCCCTGTACGCGCATGTACGCGCA 2269 /5Phos/GTTGTGCGCGTACATGCGCGTACA 734 TGTACGCTGGTGTACGCTGG 1502 /5Phos/TCCCTGTACGCTGGTGTACGCTGG 2270 /5Phos/GTTGCCAGCGTACACCAGCGTACA 735 TGTAGCATTGTGTAGCATTG 1503 /5Phos/TCCCTGTAGCATTGTGTAGCATTG 2271 /5Phos/GTTGCAATGCTACACAATGCTACA 736 TGTAGTGCCGTGTAGTGCCG 1504 /5Phos/TCCCTGTAGTGCCGTGTAGTGCCG 2272 /5Phos/GTTGCGGCACTACACGGCACTACA 737 TGTGAATCTGTGTGAATCTG 1505 /5Phos/TCCCTGTGAATCTGTGTGAATCTG 2273 /5Phos/GTTGCAGATTCACACAGATTCACA 738 TGTTCCGTGGTGTTCCGTGG 1506 /5Phos/TCCCTGTTCCGTGGTGTTCCGTGG 2274 /5Phos/GTTGCCACGGAACACCACGGAACA 739 TTAGCGCGTGTTAGCGCGTG 1507 /5Phos/TCCCTTAGCGCGTGTTAGCGCGTG 2275 /5Phos/GTTGCACGCGCTAACACGCGCTAA 740 TTAGTTGGACTTAGTTGGAC 1508 /5Phos/TCCCTTAGTTGGACTTAGTTGGAC 2276 /5Phos/GTTGGTCCAACTAAGTCCAACTAA 741 TTCCAACTTCTTCCAACTTC 1509 /5Phos/TCCCTTCCAACTTCTTCCAACTTC 2277 /5Phos/GTTGGAAGTTGGAAGAAGTTGGAA 742 TTCCGTCAGGTTCCGTCAGG 1510 /5Phos/TCCCTTCCGTCAGGTTCCGTCAGG 2278 /5Phos/GTTGCCTGACGGAACCTGACGGAA 743 TTCCTCACCGTTCCTCACCG 1511 /5Phos/TCCCTTCCTCACCGTTCCTCACCG 2279 /5Phos/GTTGCGGTGAGGAACGGTGAGGAA 744 TTCCTCCGACTTCCTCCGAC 1512 /5Phos/TCCCTTCCTCCGACTTCCTCCGAC 2280 /5Phos/GTTGGTCGGAGGAAGTCGGAGGAA 745 TTCGACCTGGTTCGACCTGG 1513 /5Phos/TCCCTTCGACCTGGTTCGACCTGG 2281 /5Phos/GTTGCCAGGTCGAACCAGGTCGAA 746 TTCGCGTGGATTCGCGTGGA 1514 /5Phos/TCCCTTCGCGTGGATTCGCGTGGA 2282 /5Phos/GTTGTCCACGCGAATCCACGCGAA 747 TTCGGAAGCGTTCGGAAGCG 1515 /5Phos/TCCCTTCGGAAGCGTTCGGAAGCG 2283 /5Phos/GTTGCGCTTCCGAACGCTTCCGAA 748 TTCTCGATTGTTCTCGATTG 1516 /5Phos/TCCCTTCTCGATTGTTCTCGATTG 2284 /5Phos/GTTGCAATCGAGAACAATCGAGAA 749 TTCTCTCTAGTTCTCTCTAG 1517 /5Phos/TCCCTTCTCTCTAGTTCTCTCTAG 2285 /5Phos/GTTGCTAGAGAGAACTAGAGAGAA 750 TTCTTGCGCGTTCTTGCGCG 1518 /5Phos/TCCCTTCTTGCGCGTTCTTGCGCG 2286 /5Phos/GTTGCGCGCAAGAACGCGCAAGAA 751 TTGAGGTCGGTTGAGGTCGG 1519 /5Phos/TCCCTTGAGGTCGGTTGAGGTCGG 2287 /5Phos/GTTGCCGACCTCAACCGACCTCAA 752 TTGCACACGCTTGCACACGC 1520 /5Phos/TCCCTTGCACACGCTTGCACACGC 2288 /5Phos/GTTGGCGTGTGCAAGCGTGTGCAA 753 TTGCGCTCTGTTGCGCTCTG 1521 /5Phos/TCCCTTGCGCTCTGTTGCGCTCTG 2289 /5Phos/GTTGCAGAGCGCAACAGAGCGCAA 754 TTGCTGCAGCTTGCTGCAGC 1522 /5Phos/TCCCTTGCTGCAGCTTGCTGCAGC 2290 /5Phos/GTTGGCTGCAGCAAGCTGCAGCAA 755 TTGGCGTCTGTTGGCGTCTG 1523 /5Phos/TCCCTTGGCGTCTGTTGGCGTCTG 2291 /5Phos/GTTGCAGACGCCAACAGACGCCAA 756 TTGGTCCTTCTTGGTCCTTC 1524 /5Phos/TCCCTTGGTCCTTCTTGGTCCTTC 2292 /5Phos/GTTGGAAGGACCAAGAAGGACCAA 757 TTGTCGAGAGTTGTCGAGAG 1525 /5Phos/TCCCTTGTCGAGAGTTGTCGAGAG 2293 /5Phos/GTTGCTCTCGACAACTCTCGACAA 758 TTGTCTGTACTTGTCTGTAC 1526 /5Phos/TCCCTTGTCTGTACTTGTCTGTAC 2294 /5Phos/GTTGGTACAGACAAGTACAGACAA 759 TTGTTCTCTCTTGTTCTCTC 1527 /5Phos/TCCCTTGTTCTCTCTTGTTCTCTC 2295 /5Phos/GTTGGAGAGAACAAGAGAGAACAA 760 AACACACGTTAACACACGTT 1528 /5Phos/TCCCAACACACGTTAACACACGTT 2296 /5Phos/GTTGAACGTGTGTTAACGTGTGTT 761 AACATCGAGTAACATCGAGT 1529 /5Phos/TCCCAACATCGAGTAACATCGAGT 2297 /5Phos/GTTGACTCGATGTTACTCGATGTT 762 AACCGAGGACAACCGAGGAC 1530 /5Phos/TCCCAACCGAGGACAACCGAGGAC 2298 /5Phos/GTTGGTCCTCGGTTGTCCTCGGTT 763 AACCTAGTAGAACCTAGTAG 1531 /5Phos/TCCCAACCTAGTAGAACCTAGTAG 2299 /5Phos/GTTGCTACTAGGTTCTACTAGGTT 764 AACGCATACTAACGCATACT 1532 /5Phos/TCCCAACGCATACTAACGCATACT 2300 /5Phos/GTTGAGTATGCGTTAGTATGCGTT 765 AACTAACCTCAACTAACCTC 1533 /5Phos/TCCCAACTAACCTCAACTAACCTC 2301 /5Phos/GTTGGAGGTTAGTTGAGGTTAGTT 766 AACTAAGGAGAACTAAGGAG 1534 /5Phos/TCCCAACTAAGGAGAACTAAGGAG 2302 /5Phos/GTTGCTCCTTAGTTCTCCTTAGTT 767 AACTCGTTCTAACTCGTTCT 1535 /5Phos/TCCCAACTCGTTCTAACTCGTTCT 2303 /5Phos/GTTGAGAACGAGTTAGAACGAGTT 768 AACTGCCGCTAACTGCCGCT 1536 /5Phos/TCCCAACTGCCGCTAACTGCCGCT 2304 /5Phos/GTTGAGCGGCAGTTAGCGGCAGTT

Each unique label may comprise two or more detectable oligonucleotide tags. The two or more tags may be three or more tags, four or more tags, or five or more tags. In some embodiments, a unique label may comprise 2, 3, 4, 5, 6, 7, 8, 9, 10, 15, 20, 30, 40, 50, 100 or more detectable tags.

The tags are typically bound to each other, typically in a directional manner. Methods for sequentially attaching nucleic acids such as oligonucleotides to each other are known in the art and include, but are not limited to, ligation and polymerization, or a combination of both (see, e.g., Green and Sambrook. Molecular Cloning: A Laboratory Manual, Fourth Edition, 2012). Ligation reactions include blunt end ligation and cohesive overhang ligation. In some instances, ligation may comprise both blunt end and cohesive overhang ligation. A “cohesive overhang” (also referred to as a “cohesive end” or an “overhang”) is a single stranded end sequence (attached to a double stranded sequence) capable of binding to another single stranded sequence thereby forming a double stranded sequence. A cohesive overhang may be generated by a polymerase, a restriction endonuclease, a combination of a polymerase and a restriction endonuclease, or a Uracil-Specific Excision Reagent (USER™) enzyme (New England BioLabs Inc., Ipswich, Mass.) or a combination of a Uracil DNA glycosylase enzyme and a. DNA. glycosylase-lyase Exonuclease VIII enzyme. A “cohesive overhang” may be a thymidine Polymerization reactions include enzyme-mediated polymerization such as a polymerase-mediated fill-reaction.

Methods for detecting and analyzing unique labels are known in the art. In some embodiments, detection may comprise determining the presence, number, and/or order of detectable tags that may comprise a unique label. For example, if the unique label may comprise detectable moieties, as described herein, fluorometry, mass spectrometry, or other detection methodology can be used for detection. In another example, if the unique label may comprise unique nucleotide sequences, a sequencing methodology can be used for detection. If the unique label may comprise both unique sequences and detectable moieties, a combination of detection methods may be appropriate, e.g., fluorometry and a sequencing reaction.

Methods of sequencing oligonucleotides and nucleic acids are well known in the art (see, e.g., WO93/23564, WO98/28440 and WO98/13523; U.S. Pat. Nos. 5,525,464; 5,202,231; 5,695,940; 4,971,903; 5,902,723; 5,795,782; 5,547,839 and 5,403,708; Sanger et al., Proc. Natl. Acad. Sci. USA 74:5463 (1977); Drmanac et al., Genomics 4:114 (1989); Koster et al., Nature Biotechnology 14:1123 (1996); Hyman, Anal. Biochem. 174:423 (1988); Rosenthal, International Patent Application Publication 761107 (1989); Metzker et al., Nucl. Acids Res. 22:4259 (1994); Jones, Biotechniques 22:938 (1997); Ronaghi et al., Anal. Biochem. 242:84 (1996); Ronaghi et al., Science 281:363 (1998); Nyren et al., Anal. Biochem. 151:504 (1985); Canard and Arzumanov, Gene 11:1 (1994); Dyatkina and Arzumanov, Nucleic Acids Symp Ser 18:117 (1987); Johnson et al., Anal. Biochem. 136:192 (1984); and Elgen and Rigler, Proc. Natl. Acad. Sci. USA 91(13):5740 (1994), all of which are expressly incorporated by reference)

Methods of detecting moieties, such as but not limited to fluorophores, are known in the art. (see, e.g., WO199641011; WO2000006770; WO2002072892; WO2007123744; Leroi V. DeSouza, K. W. Michael Siu, Ronald E. Pearlman. Mass Spectrometry: An Outsourcing Guide. Current Protocols Essential Laboratory Techniques. 2:12.2.1-12.1.18. 2009; Daman, B. and Aebersold, R. Mass spectrometry and protein analysis. Science 312:212-217. 2006.; Current Protocols in Imaging and Microscopy, and Current Protocols in Cell Biology, the entirety of which are incorporated herein by reference). In some embodiments, fluorophores such as nanocrystal quantum dots can be used to dynamically create unique combinations of labels. Quantum dots are nanometer-sized particles which may be comprised of semiconductor material that, when excited with ultraviolet light, emit specific wavelengths of light depending on the size of the nanocrystal. The emission wavelength from a given quantum dot is narrow and symmetric, thus minimizing overlap with other wavelengths and facilitating the detection of discrete quantum dots in a mixed solution. Quantum dots can be coupled to various biomolecules including, but not limited to, proteins, nucleic acids and other small molecules. Such bioconjugated quantum dots can be used to deliver fluorophores to the target molecules by various methods including, but not limited to, nucleic acid ligation, oligonucleotide annealing and protein-ligand interaction. For example, quantum dots could be bioconjugated to short double stranded nucleic acid sequences that could then be ligated to the ends of DNA molecules or bioconjugated to specific nucleic acid sequences that could anneal (hybridize) to a target or targets of interest. Discrete populations of dsDNA-quantum dot conjugates could be prepared, physically separated into either well-plates or emulsion droplets and systematically added to the ends of DNA molecules as described above. Similarly, a solid-support particle (e.g., a bead) could be attached to the ends of a population of nucleic acids. The solid-support particle would be capable of capturing bioconjugated quantum dots through protein-ligand interactions. In any of these examples, quantum dots would be added to the target molecules in a controlled manner such that the maximum population of target molecules would not exceed the number of unique combinations that could be created by the number of quantum dots available. The same exponential relationship between the number of “tags” (i.e., quantum dots) and the iterations of tag addition applies here such that the maximum number of combinations is X^(Y) where X is the number of quantum dots and Y is the number of iterations of tag addition. In any of these examples, standard methods for fluorescence detection including, but not limited to, fluorescence activated cell/particle sorting, hybridization to a fixed array of oligonucleotides, etc., could be used to detect the “signature” of a single molecule or population of molecules. In some embodiments, it may be desirable to analyze a large population of emulsion droplets to determine the unique emission wavelengths contained in a given droplet on a droplet-by-droplet basis.

Generation of Unique Labels

In some aspects, the invention provides methods for generating unique labels. The methods typically use a plurality of detectable tags to generate unique labels. in some embodiments, a unique label is produced by sequentially attaching two or more detectable oligonucleotide tags to each other. The detectable tags may be present or provided in a plurality of detectable tags. The same or a different plurality of tags may be used as the source of each detectable tag which may be comprised in a unique label. In other words, a plurality of tags may be subdivided into subsets and single subsets may be used as the source for each tag. This is exemplified in at least FIG. 1.

A plurality of tags may comprise 2, 3, 4, 5, 6, 7, 8, 9, 10, 10², 10³, 10⁴, 10⁵, or 10⁶, or more tags. Typically, the tags within a plurality are unique relative to each other.

The methods of the invention allow an end user to generate a unique label for a plurality of agents using a number of tags that are less (and in some instances far less) than the number of agents to be labeled. The number of tags may be up to or about 10-fold, 10²-fold, 10³-fold, or 10⁴-fold less than the number of agents. The number of agents to be labeled will depend on the particular application. The invention contemplates uniquely labeling at least 10³, 10⁴, 10⁵, 10⁶, 10⁷, 10⁸, 10⁹, or 10¹⁰ or more agents. In some embodiments, the agent may comprise a plurality of nucleic acids. In some embodiments, the plurality of nucleic acids may comprise at least 10³, 10⁴, 10⁵, 10⁶, 10⁷, 10⁸, 10⁹, or 10¹⁰ nucleic acids.

In certain methods of the invention, agents, detectable tags, and resultant unique labels are all present in a contained volume and are thus physically separate from other agents, detectable tags, and resultant unique labels. In some instances, the contained volume is on the order of picoliters, nanoliters, or microliters. The contained volume may be a droplet such as an emulsion droplet, a well of a multiwall plate, a tube or other container.

In some embodiments a subset of the plurality of agents is present in the same container during attachment of a detectable label. In some embodiments, the plurality of agents is separated such that each agent in the plurality is in a separate container, e.g., a well of a multiwell plate.

In some embodiments, the process of pooling and subsequently separating the plurality of agents is performed n number of times, wherein n is the number of times required to generate (m₁)(m₂)(m₃) . . . (m_(n)) number of combinations of detectable oligonucleotide tags, wherein (m₁)(m₂)(m₃) . . . (m_(n)) number of combinations of detectable oligonucleotide tags is greater than the number of the plurality of agents.

The invention provides a method which may comprise

(a) labeling two or more first subsets of agents with a detectable oligonucleotide tag to produce agents within a subset that are identically labeled relative to each other and uniquely labeled relative to agents in other subsets;

(b) combining two or more subsets of uniquely-labeled agents to form a pool of agents, wherein the pool may comprise two or more second subsets of agents that are distinct from the two or more first subsets of agents;

(c) identically labeling two or more second subsets of agents with a second detectable oligonucleotide tag to produce agents within a second subset that are uniquely labeled relative to agents in the same or different second subsets; and

(d) repeating steps (b) and (c) until a number of unique labels is generated that exceeds the number of starting agents, wherein each unique label may comprise at least two detectable oligonucleotide tags.

The invention provides another method which may comprise

(a) providing a pool of agents;

(b) separating the pool of agents into sub-pools of agents;

(c) labeling agents in each sub-pool of with one of m₁ unique detectable oligonucleotide tags thereby producing sub-pools of labeled agents, wherein agents in a sub-pool are identically labeled to each other;

(d) combining sub-pools of labeled agents to create a pool of labeled agents;

(e) separating the pool of labeled agents into second sub-pools of agents;

(f) repeating steps (c) to (e) n times to produce agents labeled with n unique detectable oligonucleotide tags, wherein the pool in (a) consists of a number of agents that is less than (m₁)(m₂)(m₃) . . . (m_(n)).

The invention provides another method which may comprise

(a) providing a population of library droplets which may comprise agents, wherein each droplet may comprise an agent;

(b) fusing each individual library droplet with a single detectable oligonucleotide tag droplet from a plurality of m₁ detectable oligonucleotide tag droplets, each detectable oligonucleotide tag droplet which may comprise a plurality of identical detectable oligonucleotide tag;

(c) labeling the agent with the detectable oligonucleotide tag in a fused droplet;

(d) harvesting labeled agents from the fused droplets and generating another population of library droplets which may comprise labeled agents; and repeating steps (b) to (d) ii times to produce agents labeled with a unique label which may comprise n detectable oligonucleotides tags, wherein the n detectable oligonucleotide tags generate an (m₁)(m₂)(m₃) . . . (m_(n)) number of combinations that is greater than the number of starting agents.

The invention provides another method which may comprise

(a) providing a population of library droplets which may comprise agents, wherein each droplet may comprise more than one agent;

(b) fusing each individual library droplet with a single detectable oligonucleotide tag droplet from a plurality of m₁ detectable oligonucleotide tag droplets, each detectable oligonucleotide tag droplet which may comprise a plurality of identical detectable oligonucleotide tag;

(c) labeling the more than one agents with the detectable oligonucleotide tag in a fused droplet;

(d) harvesting labeled agents from the fused droplets and generating another population of library droplets which may comprise labeled agents, wherein each droplet may comprise more than one agent; and

(e) repeating steps (b) to (d) n times to produce agents labeled with a unique label which may comprise n detectable oligonucleotides tags, wherein the n detectable oligonucleotide tags generate an (m₁)(m₂)(m₃) . . . (m_(n)) number of combinations that is greater than the number of starting agents and optionally wherein the agents within the same droplet are labeled identically.

In some embodiments, the unique oligonucleotide label is attached to a solid support. In some embodiments, the solid support is a bead or polymer. In some embodiments, the fill-in reaction is a polymerase chain reaction.

In another embodiment, the method may comprise:

sequentially end-labeling nucleic acids in a plurality, at their 5′ and 3′ ends, with a random combination of n detectable oligonucleotide tags,

wherein each end-labeled nucleic acid is

-   -   (a) identically labeled at its 5′ and 3′ ends, and     -   (b) uniquely labeled relative to other nucleic acids in the         plurality,

wherein each detectable oligonucleotide tags is randomly and independently selected from a number of detectable oligonucleotide tags that is less than the number of nucleic acids, and n is the number of oligonucleotides attached to an end of a nucleic acid.

In some embodiments, the further may comprise fragmenting end-labeled nucleic acids into at least a 5′ fragment which may comprise the 5′ end of the nucleic acid attached to the random combination of n detectable oligonucleotide tags and into a 3′ fragment which may comprise the 3′ end of the nucleic acid attached to the random combination of n detectable oligonucleotide tags. In some embodiments, the 5′ and 3′ fragments are about 10-1000 bases (base pairs) in length, or about 10-500 bases in length, or about 10-200 bases in length. In some embodiments, the method further may comprise sequencing the 5′ and 3′ fragments.

In another embodiment, the method may comprise:

sequencing a pair of genomic nucleic acid fragments, wherein the genomic nucleic acid fragments are attached to identical unique labels at one of their ends that indicates the genomic nucleic acid fragments were separated by a known distance in a genome prior to fragmentation.

In some embodiments, the pair of nucleic acid fragments were separated by greater than 10 kb in the genome prior to fragmentation. In another embodiment, the pair of nucleic acid fragments were separated by greater than 40 kb in the genome prior to fragmentation. In some embodiments, the method further may comprise generating the pair of genomic nucleic acid fragments by fragmenting nucleic acids which may comprise genomic sequence and identical non-genomic sequence at their 5′ and 3′ ends.

In another aspect, the invention provides compositions. In one embodiment, the composition may comprise:

a plurality of paired nucleic acid fragments attached to unique labels at one end, wherein paired nucleic acid fragments:

-   -   (a) share an identical unique label at one end that is unique in         the plurality, and     -   (b) were separated from each other in a genome by a known         distance prior to fragmentation.

In some embodiments, paired nucleic acid fragments were separated by greater than 10 kb in the genome prior to fragmentation. In another embodiment, the paired nucleic acid fragments were separated by greater than 40 kb in the genome prior to fragmentation. In some embodiments, the composition is produced using any of the methods described herein.

Examples of nucleic acids include, but are not limited to, genomic DNA, cDNA, PCR products, mRNA, total RNA, plasmids, or fragments thereof. In some embodiments, the nucleic acids are genomic DNA, cDNA, PCR products, or fragments thereof. Nucleic acids can be fragmented using methods described herein.

In some embodiments, the nucleic acids are attached to a solid support. Examples of suitable solid supports include, but are not limited to, polymers, beads, glass, nanoparticles, hydrogels or peptides. In some embodiments, the solid support is a polymer or a bead. in some embodiments, the nucleic acids are attached to the solid support with a cleavable linker as described herein.

In some embodiments, the method further may comprise fragmenting uniquely end- labeled nucleic acids. Fragmenting of nucleic acids can be accomplished by methods described herein and those well-known in the art.

In one embodiment, the method may comprise sequencing a pair of genomic nucleic acid fragments, wherein the genomic nucleic acid fragments are attached to identical unique labels at one of their ends that indicates the genomic nucleic acid fragments were separated by a known distance in a genome prior to fragmentation. In some embodiments, the known distance is greater than 5, 10, 15, 20, 30, 40, 50, 100 kb or greater separation. Genomic nucleic acid fragments can come from any organismal genomic DNA, for example, human, mammalian, bacterial, fungal or plant genomic DNA. Genomic nucleic acid fragments can be generated by fragmentation methods known in the art (see, e.g., Green and Sambrook. Molecular Cloning: A Laboratory Manual, Fourth Edition, 2012). Examples of fragmentation include, but are not limited to, enzymatic (such as a nuclease), chemical (such as a DNA nicking agent) or mechanical (such as sonication) fragmentation. Fragmentation can be random, e.g., sequence and size unspecific, or ordered, e.g., sequence dependent and/or size-restricted. The fragments generated following label addition can be tailored to the limitations of the desired detection technology. For example, the fragments can be hundreds, thousands, millions or potentially billions of base pairs in length depending on the technology used to sequence the DNA.

Fragment Amplification

Fragments can be amplified to increase the number of read pairs properly mated via their unique index combination. Amplification methods can be used to maximize fragment end recovery. These methods utilize the fragment preparation and indexing techniques described above, but vary in their approach to recovering and amplifying fragment ends within the library construction process. In one embodiment, the amplification method involves transposome-based selection and amplification. This method is shown in FIG. 36 and described in the Examples below. In another embodiment, the amplification method involves enrichment of ends via in vitro transcription. This method is illustrated in FIGS. 37a and 37b and also described in the Examples below. In a further embodiment, the amplification method involves anchored PCR. FIG. 38 shows this method and is also exemplified in the below Examples.

Additional Applications Using Unique Labeling Approaches

The invention further contemplates use of the dynamic labeling techniques described herein for a variety of other applications including but not limited to microbiological/pathogen diagnostic applications and cellular tracking, including in vivo cellular tracking, applications. Various applications that are amenable to the unique labeling methods of the invention are described in published PCT application WO2011/106536, published on Sep. 1, 2011, the entire contents of which are incorporated by reference herein.

Diagnostic/Pathogen Signature Applications

Thus, in one aspect, the methods and compositions provided herein may be used to generate molecular signatures for pathogens such as but not limited to bacteria, fungi and viruses, and may impart information about whether the bacteria have been exposed to one or more agents and if so the identity of such agent(s). In some embodiments, the agents may be anti-bacterials such as antibiotics, anti-viral, or anti-fungals.

Certain methods directed to pathogen identification may involve obtaining a sample known or suspected of containing a pathogen, concentrating and lysing any pathogens from the sample, and harvesting and detecting nucleic acids from the sample, wherein the nucleic acids are indicative of, or surrogate markers of, the pathogen(s) present in the sample. In some embodiments, the method further may comprise a step of enriching pathogens in the sample prior to concentration and lysis. The labeling methods of the invention are used to label and detect the nucleic acids from the sample, as described in greater detail below.

Certain methods directed to pathogen identification and drug susceptibility may involve obtaining a sample known or suspected of containing a pathogen, concentrating pathogens from the sample, partitioning the sample into subsets (or subpools) and exposing the subsets to different agents (e.g., antibiotics), lysing any pathogens following exposure to agent, and harvesting and detecting nucleic acids from the sample, wherein the nucleic acids are indicative of, or surrogate markers of, the pathogen(s) present in the sample. In some embodiments, the method further may comprise a step of enriching pathogens in the sample prior to concentration and lysis. In some embodiments, the sample may be cultured prior to concentration and the optionally enrichment step. The labeling methods of the invention are used to label and detect the nucleic acids from the sample, as described in greater detail below.

The foregoing methods may be carried out in microfluidic devices.

These diagnostic methods may be carried out on any number of samples including samples taken from a host (e.g., a human or an animal). These latter samples may be blood samples, urine samples, cerebrospinal fluid samples, etc.

FIG. 31 schematically illustrates a harvesting and labeling procedure that may be applied to detect the pathogen-specific nucleic acids such as those obtained through the foregoing methods. As illustrated in the Figure, a cell lysate which may comprise nucleic acid and non-nucleic acid components of a sample may be combined with a plurality of pathogen-specific nucleic acid probes. The probes may be biotinylated (shown in the Figure as “B”). The probes hybridize to their target pathogen RNA, and RNA hybridized to such probes is then physically separated from the remainder of the reaction mixture. In the Figure, the probes are biotinylated and the accordingly the probe/RNA hybrids are extracted using streptavidin (or avidin) coated beads. One of ordinary skill in the art will understand that the method may be performed using binding pairs other than biotin-avidin and using solid supports other than beads. In some instances, the RNA is mRNA.

Once the RNA is extracted, it may be initially labeled with a universal probe (i.e., a probe that hybridizes to all the RNA species). The universal probe will typically be detectably labeled (e.g., with a quantum dot or other fluorescent label or with an oligonucleotide label of the invention). This initial universal probe may indicate whether the sample was exposed to an agent, and optionally the agent type or identity. The use of this type of universal probe is not illustrated in the Figure. The Figure however does illustrate the use of another universal probe that is conjugated to digoxigenin (DIG) and that is used as a capture probe for all the harvested RNA. It is to be understood that the DIG label is exemplary and that other capture moieties may be used in its place including the oligonucleotide labels of the invention. RNA is bound to DIG-labeled universal probes and to RNA-specific, non-universal, probes that are differentially labeled. As an example, the Figure shows probes that are labeled with a set of five quantum dots (“Qdots”) but it is to be understood that they may be labeled in any manner that results in a sufficient number of unique labels, including the nucleic acid-based labels of the invention. After hybridization, pathogen RNA molecules will be bound to the capture probe (e.g., the DIG-probe) and RNA-specific (e.g., Qdot-probe). The pathogen RNAs labeled in this manner are then captured on a solid support. The RNAs are captured to the solid support via interaction of DIG and anti-DIG antibody on the solid support. It will be understood that binding pairs other than DIG and anti-DIG antibody can be used. The RNAs are then imaged. If the detected moiety is a Qdot or other fluorescent moiety, then the image detects emissions from such moieties individually (as illustrated) or in some instances in combination. The image illustrates that each RNA is detected by a region of five distinct signals. Regions having less than five signals are disregarded. The combination of particular signals within each region indicate the identity of the RNA and thus act as the signature for the RNA. Assuming that 10 different detectable moieties are used (e.g., 10 Qdots) and 5 detectable moieties are used per probe, then 252 combinations are available for labeling (i.e., there are 252 unique labels available and therefore 252 different RNA species that may be distinguished from each other). If the method further included the use of another universal probe, the region of interest might contain yet another signal corresponding to the second universal probe.

Other labeling methods are provided in FIGS. 32-34. In FIG. 32, the enriched RNA is labeled with universal capture probes (that in this Figure are either 30 base sequences that are biotinylated, as denoted by “B”, or are 50 base sequences) and with RNA-specific “labeling” probes (that in this Figure are each conjugated with a single quantum dot, but which may otherwise be labeled using the nucleic acid based labels of the invention). The configuration of the probes bound to the target RNAs is shown in the Figure, with the capture probes at the ends and the labeling probes at the internal region, thereby generating an RNA-probe complex. These complexes are then physically separated from other components of the labeling reaction mixture using streptavidin solid supports (such as beads or other surfaces) whereby the biotinylated RNAs are captured. This is followed by capture based on hybridization of the 50-mer sequence at the other end of the RNA using solid supports (such as beads or other surfaces) bound to complements of the 50-mer sequence. The RNAs are then detached from the second solid support and again captured on another streptavidin support and then imaged.

It is to be understood that the imaging methods illustrated in these Figures typically require that the RNAs are physically separated from each other and non-overlapping on a solid support. Accordingly, solid supports such as planar surfaces are suitable for such purposes.

A similar method is illustrated in FIG. 33. In this method, the capture probes are biotinylated probes and DIG-labeled probes. The initial capture step, to separate the RNA from other components in the labeling reaction mixture, uses the DIG labeled capture probe, and the final capture step, to separate RNAs from each other on a solid support (such as planar surface) uses the biotinylated capture probe.

Another method is illustrated in FIG. 34.

It is to be understood that any of the foregoing methods may be performed using a nucleic acid labeling approach as described herein rather than a fluorophore based labeling approach.

Accordingly, in some aspects, the invention provides methods of determining the sensitivity of a pathogen, e.g., a disease-causing organism such as a bacterium, fungus, virus, or parasite, to one or more agents. The agent may be a chemical agent such as a drug (e.g., antibiotic, anti-fungal, or anti-viral), or it may be a physical agent such as radiation. The methods include providing a sample known or suspected of having a pathogen and contacting the sample with one or more test agents, e.g., for less than four hours, to provide a test sample. The test sample then is treated under conditions that release RNA, such as mRNA, from the pathogen, and such RNA is exposed a plurality of nucleic acid probes. The probes may be represented by a plurality of subsets. The probes may be specific for RNA from pathogens known or suspected of being in the sample (i.e., pathogen-specific probes). Such probes may be used to determine if a particular pathogen is present and to quantitate the level of such pathogen. The probes may be pathogen-non-specific and thus able to bind to RNA from more than one pathogen. Such probes may be used to determine overall pathogen load in the sample. Such probes may also be used to identify and/or analyze pathogens that are resistant and pathogens that are susceptible to an agent. An example of such an assay is described below.

In one approach, the probes hind specifically to a target RNA, such as an mRNA, that is differentially expressed in pathogens that are sensitive to an agent as compared to pathogens that are resistant to the agent. Exposure of the target RNA and the probes occurs for a time and under conditions in which binding between the probe and target RNA can occur. The method may comprise determining a level of binding between the probe and target RNA, thereby determining a level of the target RNA, and comparing the level of the target RNA from a sample exposed to the in the presence of the test compound to a reference level, e.g., the level of the target mRNA in the absence of the test compound, wherein a difference in the level of target mRNA relative to the reference level of target mRNA indicates whether the pathogen is sensitive or resistant to the test compound.

The probes, including the pathogen-specific probes, may be labeled dynamically and/or statically, using for example the nucleic acid labeling techniques of the invention.

The pathogen may be known, e.g., an identified pathogen, or it may be an unknown pathogen, e.g., a yet to be identified pathogen. In the latter instance, the methods of the invention are used to detect a previously known pathogen.

The sample which may comprise the pathogen may be contacted with two or more agents, e.g., simultaneously or in the same sample, e.g., contacted with known or potential treatment agents, e.g., antibiotics, antifungals, antivirals, and antiparasitics. A number of these compounds are known in the art, e.g., isoniazid, rifampicin, pyrazinamide, ethambutol streptomycin, amikacin, kanamycin, capreomycin, viomycin, enviomycin, ciprofloxacin, levofloxacin, moxifloxacin, ethionamide, prothionamide, cycloserine, p-aminosalicylic acid, rifabutin, clarithromycin, linezolid, thioacetazone, thioridazine, arginine, vitamin D, R207910, ofloxacin, novobiocin, tetracycline, merepenem, gentamicin, neomycin, netilmicin, streptomycin, tobramycin, paromomycin, geldanamycin, herbimycin, loracarbef, ertapenem, doripenem, imipenem/cilastatin, meropenem, cefadroxil, cefazolin, cefalotin, cefalexin, cefaclor, cefamandole, cefoxitin, cefprozil, cefuroxime, cefixime, cefdinir, cefditoren, cefoperazone, cefotaxime, cefpodoxime, ceftazidime, ceftibuten, ceftizoxime, ceftriaxone, cefepime, ceftobiprole, teicoplanin, vancomycin, azithromycin, dirithromycin, erythromycin, roxithromycin, troleandomycin, telithromycin, spectinomycin, aztreonatn, amoxicillin, ampicillin, azlocillin, carbenicillin, cloxacillin, dicloxacillin, flucloxacillin, mezlocillin, methicillin, nafcillin, oxacillin, penicillin, piperacillin, ticarcillin, bacitracin, colistin, polymyxin B, enoxacin, gatifloxacin, lomefloxacin, norfloxacin, trovafloxacin, grepafloxacin, sparfloxacin, mafenide, prontosil, sulfacetamide, sulfamethizole, sulfanilimide, sulfasalazine, sulfisoxazole, trimethoprim, trimethoprim-sulfamethoxazole (co-trimoxazole), demeclocycline, doxycycline, minocycline, oxytetracycline, arsphenamine, chloramphenicol, clindamycin, lincomycin, ethambutol, fosfomycin, fusidic acid, furazolidone, metronidazole, mupirocin, nitrofurantoin, platensimycin, quinupristin/dalfopristin, rifampin, thiamphenicol, imidazole, cephalosporin, teicoplatin, augmentin, cephalexin, rifamycin, rifaximin, cephamandole, ketoconazole, latamoxef, or cefmenoxime.

Samples may be contacted with agents for a range of times including but not limited to 24 hours, 12 hours, 6 hours, 4 hours, less than four hours, e.g., less than three hours, less than two hours, less than one hour, less than 30 minutes, less than 20 minutes, less than 10 minutes, less than five minutes, less than two minutes, less than one minute.

These methods can be used to identify an infectious disease pathogen, e.g., a bacterium, fungus, virus, or parasite, e.g., Mycobacterium tuberculosis, e.g., detecting the presence of the pathogen in a sample, e.g., a clinical sample.

The methods include providing a test sample from a subject suspected of being infected with a pathogen, treating the test sample under conditions that release RNA such as mRNA, exposing the test sample to a plurality of nucleic acid probes, which may comprise a plurality of subsets of probes, wherein each subset may comprise one or more probes that bind specifically to a target RNA that uniquely identifies a pathogen, wherein the exposure occurs for a time and under conditions in which binding between the probe and the target mRNA can occur, and determining a level of binding between the probe and target RNA, thereby determining a level of target RNA. An increase in the target RNA of the test sample, relative to a reference sample, indicates the identity of the pathogen in the test sample. Each probe may be uniquely labeled using any of the labeling techniques of the invention, including the nucleic acid based labeling techniques.

It is to be understood that RNA may be labeled in a static manner, in a dynamic manner, or in a combination of static and dynamic manners. As used herein, static labeling refers to the generation of a unique label and affixing of the prepared unique label to a target of interest such as a single mRNA. As used herein, dynamic labeling refers to the unique labeling of a target by affixing to the target individual detectable moieties such as oligonucleotide tags or fluorescent moieties one at a time to generate a unique label. In a dynamic labeling approach, a label affixed to the target may represent information about the target. In these diagnostic methods, the label may represent whether the sample has been exposed to an agent and optionally the identity of the agent. Some labels may be used to distinguish RNA from each other. Other labels may be used to denote particular information about the RNA such as whether it came from a sample from a particular subject or from a sample treated in a particular manner. The invention contemplates that virtually any organism may be traced, identified and monitored using the methods of the invention.

The sample may be or may comprise sputum, blood, urine, stool, joint fluid, cerebrospinal fluid, and cervical/vaginal swab. Such samples may include a plurality of other organisms (e.g., one or more non-disease causing bacteria, fungi, viruses, or parasites) and/or pathogens. In some embodiments, the sample is a clinical sample, e.g., a sample from a patient or person who is or may be undergoing a medical treatment by a health care provider.

The RNA may be crude, e.g., not purified, before contact with the probes and/or may not be amplified. The cells may be lysed enzymatically, chemically, and/or mechanically. The methods may comprise use of a microfluidic device.

The methods may be used to monitor pathogen infection, e.g., incidence, prevalence, for public health surveillance of an outbreak of a pathogen, e.g., a sudden rise in numbers of a pathogen within a particular area.

The sample may be obtained from a subject such as but not limited to humans and animals, such as laboratory animals, e.g., mice, rats, rabbits, or monkeys, or domesticated and farm animals, e.g., cats, dogs, goats, sheep, pigs, cows, horses, and birds, e.g., chickens.

The methods may further comprise determining and/or selecting a treatment for the subject and optionally administering the treatment to the subject, based on the outcome of an diagnostic assay as described herein.

In another general aspect, the invention features methods of selecting a treatment for a subject. The methods include optionally identifying an infectious disease pathogen (e.g., detecting the presence and/or identity of a specific pathogen in a sample), e.g., using a method described herein, determining the drug sensitivity of the pathogen using the methods described herein, and selecting a drug to which the pathogen is sensitive for use in treating the subject.

In yet another aspect, the invention provides methods for monitoring an infection with a pathogen in a subject. The methods include obtaining a first sample which may comprise the pathogen at a first time, determining the drug sensitivity of the pathogen in the first sample using the method described herein, optionally selecting a treatment to which the pathogen is sensitive and administering the selected treatment to the subject, obtaining a second sample which may comprise the pathogen at a second time, determining the drug sensitivity of the pathogen in the second sample using the method described herein, and comparing the drug sensitivity of the pathogen in the first sample and the second sample, thereby monitoring the infection in the subject. In some embodiments of the methods described herein, the subject is immune compromised.

In some embodiments of the methods described herein, the methods include selecting a treatment to which the pathogen is sensitive and administering the selected treatment to the subject, and a change in the drug sensitivity of the pathogen indicates that the pathogen is or is becoming resistant to the treatment, e.g., the methods include determining the drug sensitivity of the pathogen to the treatment being administered. in some embodiments, a change in the drug sensitivity of the pathogen indicates that the pathogen is or is becoming resistant to the treatment, and the method further may comprise administering a different treatment to the subject.

In yet another aspect, the invention features methods of monitoring an infection with a pathogen in a population of subjects. The methods include obtaining a first plurality of samples from subjects in the population at a first time, determining the drug sensitivity of pathogens in the first plurality of samples using the method described herein, and optionally identifying an infectious disease pathogen in the first plurality of samples using the method described herein, optionally administering a treatment to the subjects, obtaining a second plurality of samples from subjects in the population at a second time, determining the drug sensitivity of pathogens in the second plurality of samples using the method described herein, and optionally identifying an infectious disease pathogen in the first plurality of samples using the method described herein, comparing the drug sensitivity of the pathogens, and optionally the identity of the pathogens, in the first plurality of samples and the second plurality of samples, thereby monitoring the infection in the population of subject.

“Infectious diseases” also known as communicable diseases or transmissible diseases, comprise clinically evident illness (i.e., characteristic medical signs and/or symptoms of disease) resulting from the infection, presence, and growth of pathogenic biological agents in a subject (Ryan and Ray (eds.) (2004). Sherris Medical Microbiology (4th ed.). McGraw Hill). A diagnosis of an infectious disease can confirmed by a physician through, e.g., diagnostic tests (e.g., blood tests), chart review, and a review of clinical history. In certain cases, infectious diseases may be asymptomatic for some or all of their course. Infectious pathogens can include viruses, bacteria, fungi, protozoa, multicellular parasites, and prions. One of skill in the art would recognize that transmission of a pathogen can occur through different routes, including without exception physical contact, contaminated food, body fluids, objects, airborne inhalation, and through vector organisms. Infectious diseases that are especially infective are sometimes referred to as contagious and can be transmitted by contact with an ill person or their secretions.

As used herein, the term “gene” refers to a DNA sequence in a chromosome that codes for a product (either RNA or its translation product, a polypeptide). A gene contains a coding region and includes regions preceding and following the coding region (termed respectively “leader” and “trailer”). The coding region is comprised of a plurality of coding segments (“exons”) and intervening sequences (“introns”) between individual coding segments.

The term “probe” as used herein refers to an oligonucleotide that binds specifically to a target such as a nucleic acid such as mRNA. A probe can be single stranded at the time of hybridization to a target.

16S Amplicon Tagging

In another embodiment, the labeling methods described herein can be used to characterize pathogen populations by labeling nucleic acid regions of interest. For example, the 16S region in a bacterium can be used to identify and distinguish species of bacteria present in a sample. The 16S region is the target of numerous studies that seek to characterize the microbial community present in a given sample (e.g., human microbiome studies). The prokaryotic 16S ribosomal RNA is composed of 4 different subunits spanning approximately 1,500 base pairs in length. Current sequencing technologies make it difficult and in some cases impossible to accurately characterize the 16S region due to either prohibitively high error rates or long read lengths. To overcome these problems, the 16S region may he analyzed by PCR using primers designed to amplify each of the 4 subunits separately. The method described herein is unique in that it allows for tagging amplicons from a large population of individual cells such that an explicit and identifiable association can be made among all 4 amplicons on a cell-by-cell basis. Once tagged, all downstream sample processing can be performed in bulk, which allows for both workflow streamlining and cost reduction. Importantly, additional tagging information can be added to these samples downstream allowing for the capture of additional layers of sample history information.

FIG. 35 is a schematic showing an exemplary technique for amplifying and tracking 16S regions using the methods and labels described herein. For this technique, cells are distributed into an emulsion such that each droplet only contains a single cell. The single cell emulsion is then merged to a previously constructed droplet library containing PCR primers designed to amplify each of the four 16S regions. Although each primer is designed to amplify a specific region, every primer carries a common (universal) tailing sequence. Cells may be lysed either prior to droplet merging or during PCR amplification of the 16S amplicons. Following PCR, a single bead carrying a unique index sequence (e.g., a detectable oligonucleotide tag created using the methods described herein) is added to each droplet through droplet merging, picoinjection, etc. Although each bead carries a unique index sequence, it also carries a common sequence complimentary to the universal tail present on the PCR primers. Following annealing of the amplicons to the beads via the universal tail sequence, the amplicons become covalently linked to the bead via a polymerization (extension) reaction. Once attached to the beads, the emulsion can be broken and all downstream processing can be performed in bulk.

Any desirable solid support can be used in place of beads, e.g., polymers, glass, nanoparticles, hydrogels or peptides. Alternatively, labeling can be performed in the absence of a solid support (e.g., in an emulsion). Agents other than 16S ribosome amplicons can be labeled, e.g., a nucleic acid such as a portion of a genome, a gene, a promoter, a coding sequence of a gene, a cDNA, or an RNA. Use of emulsion droplets can be replaced with separation of agents, e.g., using microwells or tubes. This technique is useful generally for assessing any sample (e.g., a cell, a genome, a transcriptome, a sample containing multiple organisms or cells) where prohibitively high error rates and/or long read lengths are an issue.

RNA Extraction and Analysis

RNA can be extracted from cells in a sample, e.g., a pathogen cell or clinical sample, by treating the sample enzymatically, chemically, or mechanically to lyse cells the sample and release mRNA. It will be understood by skilled practitioners that other disruption methods may be used in the process.

The use of enzymatic methods to remove cell walls is well-established in the art. The enzymes are generally commercially available and, in most cases, were originally isolated from biological sources. Enzymes commonly used include lysozyme, lysostaphin, zymolase, mutanolysin, glycanases, proteases, and mannose.

Chemicals, e.g., detergents, disrupt the lipid barrier surrounding cells by disrupting lipid-lipid, lipid-protein and protein-protein interactions. The ideal detergent for cell lysis depends on cell type and source. Bacteria and yeast have differing requirements for optimal lysis due to the nature of their cell wall. In general, nonionic and zwitterionic detergents are milder, The Triton X series of nonionic detergents and 3-[(3-Chollami dopropyl)dimethylammonio]-1-propanesulfonate (CHAPS), a zwitterionic detergent, are commonly used for these purposes. In contrast, ionic detergents are strong solubilizing agents and tend to denature proteins, thereby destroying protein activity and function. SDS, an ionic detergent that binds to and denatures proteins, is used extensively in the art to disrupt cells.

Physical disruption of cells may entail sonication, French press, electroporation, or a microfluidic device which may comprise fabricated structures can be used to mechanically disrupt a cell. These methods are known in the art.

RNA extraction can be coupled with the labeling methods described herein in order to characterize transcripts present in a single cell or population of cells. Currently available platforms/techniques such as the Fluidigm C1 instrument enable the study of the transcriptomes at the single cell level. The throughput of such instruments, however, is comparatively low. The C1 instrument, for example, allows for the parallel processing of up to 96 cells. The methods described herein allows for scalable, massively parallel processing of single cells in numbers that are orders of magnitude beyond any currently available platforms.

Labeling for Quantitative Analysis of Agents

Also contemplated herein is a method of labeling agents such that quantitative information about the agents can be extracted. Quantitative information includes the number or level of an agent present in a sample or cell. Examples include transcript expression levels in a cell or a sample, chromosome copy numbers in a cell or a sample, and number of PCR amplicons in a sample, This method can be used, inter alia, to quantify relative number or level of a transcript in a cell or tissue, or relative number or level of a cell such as bacteria in a sample.

In an exemplary method, a solid support, such as a bead or polymer, carries a plurality of nucleic acid labels. The nucleic acid labels on a bead contain common sequences (i.e., sequences present on all the labels on a single solid support) and unique sequences (i.e., sequences that distinguish each label from other labels on the solid support). The common sequences include a capture sequence such as a poly(dT) sequence. Common capture sequences may be common throughout all solid supports used in a particular analysis (e.g., if all solid supports are used to capture transcripts, then all labels may comprise a common poly(dT) sequence. The common sequences also include a first detectable oligonucleotide sequence or tag (which may be comprised of one or more index sequences). This first detectable oligonucleotide sequence or tag is unique to the solid support (i.e., it distinguishes the solid support from other solid supports, and thus distinguishes the plurality of transcripts bound to the solid support from other pluralities of transcripts bound to other solid supports). In this way, transcripts from a single cell may be identified as such. The nucleic acid label may also contain a unique sequence. This unique sequence is referred to as the second detectable oligonucleotide sequence or tag and it may be comprised of one or more index sequences). This sequence differs between labels on a single solid support so that each label may comprise a unique sequence. The first and second detectable oligonucleotide sequences may be generated using the methods described herein.

The detectable oligonucleotide sequences may be generated apart from the solid support and then attached to it. Alternatively, the sequences may be generated while attached to the support. As an example, the first detectable oligonucleotide sequence may be first generated and then attached to the solid support, following which the second detectable oligonucleotide sequence is generated directly on the support. In some embodiments, the second sequence is attached to the first sequence by combining an excess of the second sequences to the first sequences (which may or may not be attached to the solid support). Attachment may occur e.g., by ligation or polymerase-mediated attachment. The ensures that the solid support is exposed to a very large number of second sequences, much larger than the number of first sequences present on the solid support, such that each nucleic acid label on the solid support contains a unique second sequence. The labeling of the solid support could thus be performed as a bulk reaction with a large number of the previously first-sequence-labeled solid supports present in the same reaction. Alternatively, the first and second sequences are generated to form the nucleic acid label and then attached to the solid support.

As another alternative, nucleic acid labels appropriate for quantitative analysis are generated and used in the absence of a solid support (e.g., in an emulsion). The nucleic acid labels, either present on a solid support or alone, are then associated with one or more agents. A population of agents (e.g., RNA transcripts from a single cell) are uniquely labeled compared to other populations of agents using the first sequence (i.e., the common but not capture sequence) of the nucleic acid label. Subgroups of agents or individual agents (e.g., a single RNA transcript in a pool of RNA transcripts from a single cell) are uniquely labeled compared to other subgroups of agents or other individual agents in the same population using the second nucleic acid (i.e., the unique sequence) of the nucleic acid label. Thus, the number of subgroups or individual agents present in a population can be quantified.

In the example of quantitative transcriptome analysis, a sample containing multiple cells is processed and put into an emulsion such that droplets are formed. Cells are lysed either immediately prior to droplet formation (e.g., hypotonic lysis) or once they have already been encapsulated in an emulsion (e.g., freeze-thaw cycling), releasing the mRNA from the cell into the droplet. A single bead containing nucleic acid labels generated as described above is then introduced into the droplet (e.g., by droplet merging or picoinjection). Each nucleic acid label contains, in addition to the first (common) and second (unique) sequences, an oligo(dT) capture sequence that binds to the polyA tail present on each mRNA transcript. Each nucleic acid label captures one mRNA and is processed through a first strand cDNA synthesis reaction to create a copy of the RNA sequence that is covalently linked to the labeled solid support. Each copy of the mRNA sequence will then contain the first sequence of the nucleic acid label, which is common to every mRNA on the same solid support, and the second sequence of the nucleic acid label, which is unique to every individual mRNA in the same solid support. This allows for the number of original mRNA molecules to be quantified, as each original individual mRNA will have a unique sequence that is carried through further processing and/or amplification.

Cell Tracking Applications

In still other aspects, the invention provides methods of tracking cells by uniquely labeling such cells using methods of the invention and/or variations thereof. For example, the invention contemplates that cells may be uniquely labeled using viruses that stably integrate into the genome at random positions. Such cells may be administered to a subject and the effect of such cells monitored. Such cells may be further labeled using the same or different viruses that stably integrate into the genome. It is to be understood that in some instances the unique labeling of the cells using such viruses results not from the virus itself, since the same viral sequence will integrate into a plurality of cells, but rather from the particular location of integration of the virus. If the virus is engineered to carry and integrate a primer sequence (along with the viral sequence), then it and its neighboring sequence at the site of integration can be amplified and sequenced, and thereby distinguished from other integration events.

The invention contemplates that a cell may be infected with a virus, including a different virus, per condition to which it is exposed. For example, a population of cells may be initially infected with virus A and then subsequently infected with virus B upon exposure to condition B. Viruses A and B are able to stably integrate into the genome of the host subject and their particular integration patterns will differ from and likely be unique compared to the integration patterns in another cell. In this way, cells may be uniquely labeled, including labeled in a dynamic manner to reveal information about the cell such as prior history of the cell.

Reference can be made to Lu et al. Nature Biotechnology, 2011, 29(10):928-934, the entire teachings of which are incorporated by reference herein.

Tagging Epigenetics Constructs

In a further embodiment, the solid supports including beads have been labeled using the combinatorial split-pool synthesis methods to generate a population of identically labeled oligos attached to the solid support. These oligos may be cleavable such that they can be released into, for example, a multi-well plate or a droplet and ligated onto the free ends of DNA bound by chromatin or any other nucleic acids in the cell. These released oligos contain the barcode generated by split pool synthesis and a T7 promoter such that only the nucleic acids ligated by the oligos are amplified in an in vitro transcription reaction following emulsion breaking. This allows for the single cell labeling of Chromatin states as described in PCT/US2013/029123 and published as WO 2013/134261, the entire contents of which are incorporated by reference herein.

Labeling Nucleic Acid-Protein Complexes

The methods described above can also be used to label various nucleic acid-protein complexes. Methods such as chromatin immunoprecipitation (e.g., ChIP and ChIA-PET), chromosome conformation capture (e.g., 3C and Hi-C) and various RNA-protein pull-down methods are designed to associate (crosslink) nucleic acids to various proteins.

The three-dimensional (3D) conformation of chromosomes is involved in compartmentalizing the nucleus and bringing widely separated functional elements into close spatial proximity. Understanding how chromosomes fold can provide insight into the complex relationships between chromatin structure, gene activity, and the functional state of the cell. Long-range interactions between specific pairs of loci can be evaluated with chromosome conformation capture (3C), using spatially constrained ligation followed by locus-specific polymerase chain reaction (PCR). Adaptations of 3C have extended the process with the use of inverse PCR (4C) or multiplexed ligation-mediated amplification (5C). Still, these techniques require choosing a set of target loci and do not allow unbiased genome wide analysis. The method. Hi-C adapts the above approach to enable purification of ligation products followed by massively parallel sequencing. Hi-C allows unbiased identification of chromatin interactions across an entire genome. Aspects of the method include cells being crosslinked with formaldehyde; DNA being digested with a restriction enzyme that leaves a 5′ overhang; the 5′ overhang is filled, including a biotinylated residue; and the resulting blunt-end fragments are ligated under dilute conditions that favor ligation events between the cross-linked DNA fragments. The resulting DNA sample contains ligation products having fragments that were originally in close spatial proximity in the nucleus, marked with biotin at the junction. A Hi-C library may then be created by shearing the DNA and selecting the biotin-containing fragments with streptavidin beads. The library is then analyzed by using massively parallel DNA sequencing, producing a catalog of interacting fragments. This is further described in Lieberman-Aiden E et al., Comprehensive mapping of long-range interactions reveals folding principles of the human genome, Science. 2009 Oct 9;326(5950):289-93, the contents of which are incorporated herein in their entirety. Thus, instead of using processes such as circularization to covalently link nucleic acids together within a given complex, the labeling methods described above can he leveraged in order to uniquely label the components of each complex.

EXAMPLES

The following Examples are meant for illustrative purposes, and are not meant to be exclusive or limiting. Each Example illustrates a method for labeling a specific type of construct (e.g., genomic DNA or a solid support), but it is to be understood that these methods also apply to any type of constructs that can be attached to an oligonucleotide by some means. For example, covalent attachment of a nucleotide adapter to a non-nucleotide-based construct, e.g. a protein, a cell, or a chemical, would allow for addition of unique oligonucleotide labels to a non-nucleotide-based constructs.

Example 1 Polymerase-Mediated Bioinformatic Association of Nucleic Acid Ends for Mate-Pair Analysis

Generation of End-Labeled Genomic DNA Fragments

A method for bioinformatically associating the ends of genomic DNA is outlined in FIG. 1. Genomic DNA is fragmented and size selected to a known size using techniques known in the art (e.g., sonication, cavitation, point-sink or mechanical shearing, or a DNA fragmenting enzyme and size-exclusion columns or gel purification). The genomic DNA is then A-tailed and ligated to a biotinylated, T-tailed asymmetric oligonucleotide adapter using methods known in the art (see, e.g. Maniatis, Molecular Cloning). Klenow exo-enzyme is commonly used to add a single nucleotide to the 3′ termini of DNA fragments). The adapter is a partial duplex to allow for annealing of the single-stranded oligonucleotide indexes described below.

One or more index libraries (preferably 1-4 libraries) are created such that each library contains approximately >1000 unique single-stranded oligonucleotide indexes, thus approximately 2000-4000 unique indexes are used. Index libraries may be created in droplets using standard flow focusing techniques (ref) or placed in the wells of standard laboratory plasticware (e.g., 384-well or 1152-well plates). For a given library, each droplet/well will contain many copies of one unique single-stranded index. Droplets/wells may contain some or all of the key components of a polymerase fill-in reaction (e.g., MgCl₂, dNTP, and Polymerase). Each unique single-stranded oligonucleotide index contains 3 distinct regions: sequence complimentary to the adapter (Ad) or to a previously added index sequence (B or C), a unique index sequence (Idx), and a sequence used to “capture” the next index oligonucleotide index which contains one or more dUTP nucleotides (B′/C′).

Fragmented genomic DNA ligated to an adapter is diluted to a desired concentration to control the number of molecules per droplet/well (e.g., a single DNA molecule per droplet/well or more than a single DNA molecule per droplet/well) and merged with (see above references for droplet merging)/added to the first index library (Library “A” in FIG. 1.).

The Ad region of each unique single-stranded oligonucleotide index binds to the adapter on each end of the fragmented genomic DNA molecule. A polymerase-mediated fill-in reaction is performed in each droplet, creating the complement to the index and capture regions on the each unique single-stranded oligonucleotide index a, and thus generating unique double-stranded oligonucleotide indexes.

If emulsion droplets are utilized, they are then broken using various mechanical or chemical reagents depending on the oil/surfactant utilized in the emulsion, resulting in the combination and mixing of the DNA from each droplet. If standard plastic labware is used, samples in all wells are pooled together, resulting in the combination and mixing of the DNA from each well. Mixed DNA is the treated with USER™ enzyme (Uracil-Specific Excision Reagent, New England. BioLabs Inc., Ipswich, Mass.), causing the capture portion of the double-stranded oligonucleotide index to be digested due to the presence of one or more dUTP nucleotides. This digestion reveals the nascent strand, which is complementary to a sequence contained in the next library of indexes (Library “B” in FIG. 1).

The process of fragmented genomic DNA dilution, merging with a droplet library or mixing in standard labware, polymerase fill-in, breaking the droplets or pooling the wells, and treatment with USER™ enzyme is repeated for the desired number of cycles, each time adding one new unique oligonucleotide index sequence to both ends of the fragmented genomic DNA.

After the final index addition, the result is fragmented genomic DNA uniquely end-labeled on both the 5′ and 3′ end with a unique label made up of many oligonucleotide indexes. The uniquely end-labeled fragmented genomic is then fragmented and the ends are collected via streptavidin beads, which recognized the biotin label on the adapter. Fragments can be ligated to technology specific sequencing adapters (e.g., lumina adapters) and sequenced. Ends are informatically paired by matching the unique label on one fragment of DNA with the same unique label on the other fragment of DNA (see FIG. 3E).

This method of bioinformatics association can also be used with other types of nucleic acids, such as RNA, cDNA, or PCR-amplified DNA, or any other type of construct where such a labeling scheme is required. This method can also be performed in well plates instead of emulsion droplets. To accomplish this, arrays of oligonucleotide indexes are prepared in 384-well (or 1536-well) plates. 1 to 4 index arrays are created, each containing ˜1000 unique indexes for a total of ˜1000-4000 unique indexes. Fragmented genomic DNA is aliquoted into at least one index array 384-well (or 1536-well) plate at a desired density. After the index is attached to the fragmented genomic DNA, the index-labeled fragmented genomic DNA is optionally purified and then pooled together with the other index-labeled fragmented genomic DNA molecules. The index-labeled fragmented genomic DNA molecules are then redistributed to a second set of index arrays either containing the same set of unique indexes previously used or new unique indexes. The pooling of the index-labeled fragmented genomic DNA molecules causes mixing or shuffling such that redistribution to a second set of indexes is random, minimizing the possibility that multiple index-labeled fragmented genomic DNA molecules contain the same series of indexes that make up the unique label.

Example 2 Ligation-Mediated Bioinformatic Association of Nucleic Acid Ends in Emulsions for Mate-Pair Analysis

Validation of Ligation in Emulsions

A 34 bp adapter was designed. The adapter was biotinylated and A-tailed to force directionality of ligation. Ligation was performed in an tube or an emulsion using 50 ng of lambda DNA and 50 ng of adapter. Lambda DNA was used as it is unlikely to form circles. Droplets were created by standard techniques (e.g., flow focusing at a T-junction using a PDMS-based microfluidic chip). Channel 1 contained DNA in ligase buffer (500 microliters) and channel 2 contained Quick Ligase in ligase buffer (500 microliters). PCR primers were designed to amplify internally within the lambda DNA (ligation-independent) or to amplify a portion of the adapter and the 5′ or 3′ end of the lambda DNA (ligation-dependent). Negative controls were performed in tubes to ensure ligation was ligase-dependent.

FIG. 2 shows that ligation was achieved in both tubes and emulsion droplets, although ligation can also be achieved in other methods involving, for example, high-throughput plates. The forward primer for the adapter and the 5′ primer for the lambda DNA only amplified in the presence of ligase, indicating that the adapter and the 5′ end of the lambda DNA had ligated together in both tubes and emulsion droplets. The same result was achieved using the reverse primer for the adapter and the 3′ primer for the lambda DNA, indicating that the adapter and the 3′ end of the lambda DNA had ligated together in both tubes and emulsion droplets. These results demonstrate that ligation can be successfully performed in both tubes and emulsion droplets.

Generation of End-Labeled Genomic DNA Fragments

A method for bioinformatically associating the ends of genomic DNA is outlined in FIG. 3. Genomic DNA is fragmented and size selected to a known size using techniques known in the art as described in Example 1. The genomic DNA is then A-tailed and ligated to a biotinylated, T-tailed asymmetric oligonucleotide adapter using methods well known in the art as described in Example 1.

Multiple droplet libraries (preferably 2-4 libraries) are created such that each library contains approximately 1000 unique double-stranded oligonucleotide indexes, thus approximately 2000-4000 unique indexes are used. For a given library, each droplet will contain many copies of one unique double-stranded index. Droplets may contain some or all of the key components of a ligation reaction (e.g., MgCl₂, ATP, Ligase).

Fragmented genomic DNA ligated to an adapter is diluted to a desired concentration to control the number of molecules per droplet (e.g., a single DNA molecule per droplet or more than a single DNA molecule per droplet) and merged with the first index droplet library (Droplet Library “A” in FIG. 3).

A ligation reaction is performed in each droplet, joining each unique double-stranded oligonucleotide index to the adapter on each end of the genomic DNA. The emulsion is then broken and the DNA is phosphorylated so that a second index can be ligated to the end of the first index.

The process of fragmented genomic DNA dilution, merging with a droplet library (e.g. Droplet Library “B” or “C” in FIG. 3), ligation, breaking the droplets, and phosphorylation is repeated for the desired number of cycles, each time adding one new unique oligonucleotide index sequence to both ends of the fragmented genomic DNA.

After the final index addition, the result is fragmented genomic DNA uniquely end-labeled on both the 5′ and 3′ end with a unique label made up of many oligonucleotide indexes. The uniquely end-labeled fragmented genomic is then further fragmented and the ends are collected via streptavidin beads, which recognized the biotin label on the adapter. Fragments can be ligated to technology specific sequencing adapters (e.g., Illumina adapters) and sequenced. Ends are informatically paired by matching the unique label on one fragment of DNA with the same unique label on the other fragment of DNA as described in Example 1.

As with Example 1, this method can be used for other types of nucleic acids, such as RNA, cDNA, or PCR-amplified DNA, or any other type of construct where such a labeling scheme is required. Also as with Example 1, this method can be performed in well plates instead of emulsion droplets.

Validation of Ligation-Mediated End-Labeling

Three libraries were created “in bulk” in microcentrifuge tubes from fragmented, end-repaired, A-tailed E. coli genomic DNA. For all three libraries, an initial ligation reaction was performed to add on a generic adapter to the ends of the E. coli genomic DNA. Genomic DNA libraries were then subjected to 1 (Library 1), 2 (Library 2), or 3 (Library 3) rounds of index ligation. Index ligation was performed by joining unique double-stranded oligonucleotide indexes to the adapter on each end of the genomic DNA. If required, the DNA was phosphorylated so that a second index could ligated to the end of the first index (two rounds of index ligation) or a third index could be ligated to the end of a second index (three rounds of index ligation). For round 1 and round 3 of index ligation, the same library/pool of indexes was used (pool A). For round 2, a library/pool of different indexes was used (pool B). As a final step, Illumina indexed adapters were ligated to all three genomic DNA libraries. Libraries were then pooled and sequence on an Illumina MiSeq (Illumina, San Diego, Calif.) using standard Illumina sequencing primers. Paired reads were identified and analyzed en masse (i.e. data from read 1 (3′ end read) and read 2 (5′ end read) was analyzed together as a single population). Sequencing data was analyzed by breaking up the reads into four separate, linear 8-mer populations (i.e. positions 1 through 4 in the read), since the indexes were each 8 bp in length. For each position, the number of reads containing index or adapter were measured.

FIG. 4 depicts the results of the total read population analysis (i.e., en masse analysis) of the index ligation method. Library 1, which underwent 1 round of index ligation, had an expected outcome of an index read in position 1 and an adapter read in position 2. Library 2, which underwent 2 rounds of index ligation, had an expected outcome of an index read in position 1 and 2 and an adapter read in position 3. Library 3, which underwent 3 rounds of index ligation, had an expected outcome of an index read in position 1 to 3 and an adapter read in position 4.

FIG. 5 depicts the results of read pair analysis of individual molecules that underwent the index ligation method. Instead of analyzing the data from read 1 (3′ end read) and read 2 (5′ end read) together, reads were paired so that a molecule-by-molecule analysis was performed. First, reads were paired based on their unique read identifier. Each read was then broken down into 4 positions (8-mers) per read as described above. For each library, the total number of read pairs and the total number of unique molecular outcomes were determined and are shown in FIG. 5. The composition of the top 10 most prevalent molecular outcomes and the number of pairs for each outcome are also shown in FIG. 5. It was determined that the most desired outcome (the correct expected outcome) occurred 6% of the time in Library 1, 4% of the time in Library 2, and 4% of the time in Library 3.

Thus, FIGS. 4 and 5 show that the expected outcome was achieved and thus index ligation is a valid method of generating a unique label.

Example 3 Ligation-Mediated Oligonucleotide-Based Unique Labels Attached to Solid Supports

Solid support particles (e.g. beads or a polymer) are purchased or provided and conjugated to a cleavable linker (photo- or chemically cleavable). Each solid support has a vast number of binding sites on its surface. FIG. 6 shows a single binding site on a bead for illustrative purposes. The cleavable linker in FIG. 6 shows a double-stranded DNA (dsDNA) linker, but the cleavable linker can be any substrate that supports the covalent addition of a dsDNA.

Arrays of dsDNA oligonucleotide indexes are prepared in 384-well (or 1536-well) plates. 2 to 4 index arrays are created, each containing ˜1000 unique indexes for a total of ˜2000-4000 unique indexes.

Solid supports are aliquoted into 384-well (or 1536-well) plates at a desired density. Using a liquid handling robot, ligase buffer and ligase enzyme are added to the solid support plates. An aliquot of index array “A” is then added to the plates (FIG. 6).

Following ligation of the “A” index to the solid supports, solid supports are pooled using a liquid handling robot, collected (e.g., using a standard magnet for paramagnetic beads or a centrifuge for beads or polymers), and washed to remove unwanted material.

A kinase reaction is then performed in order to permit the addition of the next index.

Solid supports are then resuspended and aliquoted into 384-well (or 1536-well) plates at a desired density. This mixing or shuffling randomly redistributes the solid supports, minimizing the possibility that multiple solid supports contain the same series of indexes that make up the unique label.

Index ligation is repeated 2-4 times. For example, the above steps are repeated with index array “B” and then again with index array “C” as illustrated in FIG. 6. Upon completion of this method, uniquely-labeled solid supports are generated, wherein each solid support has multiple copies of the same unique label made up of an index A sequence, an index B sequence, and an index C sequence but has a different unique label than other solid supports. The mixing and redistribution of the solid supports after each addition of an index sequence makes it unlikely that two solid supports will carry the same unique label. To illustrate this, after 3 successive rounds of index ligation, the population of solid supports can accommodate >10⁹ unique labels.

The uniquely-labeled solid supports can then be further modified to include a capture oligo (e.g., oligo-dT or a sequence specific capture probe). Alternatively, the uniquely-labeled solid supports can be used “as is” for ligation or binding of agents DNA, RNA, cells, polymers, proteins, etc.).

This method, for example, can be performed in common plastic ware (e.g. well plates) or emulsion droplets.

This method can be also adapted to create discrete libraries of uniquely labeled solid supports as shown in FIG. 7. Indexes and solid supports aliquoted into well plates as described above. Index array “A” is added to each plate of solid supports and ligated to the solid supports. A liquid handling robot is used to wash the solid supports and remove unwanted material. Solid supports are not pooled, but instead are kept separate. Index array “B” is then added to each plate of solid supports and ligated to the solid supports. This is repeated with Index array “C”. This method generates many solid supports with the same unique label contained within the same well. This method, for example, can be performed in common plastic ware (e.g. well plates) or emulsion droplets.

Example 4 Microbiome Typing Using Unique Labels

FIG. 8 depicts an exemplary method for identifying multiple species of bacteria contained within a microbiome. A microbiome sample is isolated (e.g. from the gut of an animal or from a sample in the environment such as a water source) as is known in the art. Individual cells are suspended in emulsions and lysed by methods known in the art (e.g., chemical lysis).

16S rRNA primers tailed with a recognition site (in order to identify the ends of the 16S rRNA gene after sequencing) and PCR mix are picoinjected into each emulsion droplet in order to amplify the full-length 16S rRNA gene. The 16S rRNA gene has been used previously for phylogenetic studies as it is highly conserved between different species of bacteria and archaea. Universal primers are used to amplify the 16S rRNA gene from different species (e.g. 27F and 1492R or 27F and 534R from Weisburg, Barns, Pelletier and Lane. 16S ribosomal DNA amplification for phylogenetic study. J. Bacteriol. January 1991 vol. 173 no. 2 697-703). 16S rRNA gene sequences contain hypervariable regions that provide species-specific signature sequences useful for bacterial identification. After amplification, a DNA fragmenting agent (e.g., Fragmentase® from New England BioLabs Inc., Ipswich, Mass.) is added to produce random small fragments compatible with current sequencing technology (e.g., approximately 200 bp). Fragmentase® is inactivated by addition of 0.5 M EDTA, by heat inactivation, or by allowing the reaction to run to completion.

3 rounds of index ligation are performed as described in Example 2 to label all of the 16S fragments contained within a single emulsion droplet with the same label containing 3 indexes. In this method, each all of the fragments in each droplet will be identically labeled compared to each other but uniquely labeled compared to fragments contained in other droplet.

After completion of the index ligation, the emulsion droplets are broken and the 16S fragments pooled. The 16S fragments from multiple different microbes can then be sequenced at the same time. Sequencing is performed on standard commercial machines as is known in the art, e.g., Illumina Sequencing (Illumina, San Diego, Calif.).

The sequencing reads are then binned according to the common unique label “barcode” and a “mini-assembly” of the region from overlapping regions and known ends (from the recognition site on the primers) is performed. Thus, a computational re-assembly of the 1.5 Kb 16S region is performed from individual microbes.

Example 5 Other Methods of Generating Unique End-labeled Nucleic Acids

The following methods describe addition of one or two index sequences to create a unique end-labeled nucleic acid. It is to be understood that more than one or two index sequences can be added by repeating the steps required to add an additional index sequence. As a result, a unique end-labeled nucleic acid could have three or more index sequences per unique label.

FIG. 9 depicts a method using polymerase and single-stranded index oligo sequences. Genomic fragments, size selected are generated and ligated to an adapter as described in Example 1. Emulsion droplets are prepared with one genomic fragment ligated to an adapter per droplet. The genomic fragment is melted (e.g., by heating the double stranded fragment to produce two single stranded fragments) and each droplet is merged with an “A” droplet that contains multiple copies of a single stranded oligonucleotide index “A_(i)”. Each “A_(i)” single stranded index includes three distinct sequence moieties: 1) the reverse complement of the adapter sequence, 2) a unique index sequence, and 3) a priming site for the next single stranded oligonucleotide index. The single stranded oligonucleotide index “A_(i)” hybridizes to the adapter attached to the genomic fragment in each merged droplet. Each merged droplet is then merged with a “B” droplet that contains multiple copies of a single stranded oligonucleotide index “B_(i)”. Each “B_(i)” single stranded index includes two distinct sequence moieties: 1) the reverse complement of the priming site in “A_(i)” and 2) a unique index sequence. Each “B” droplet also contains a polymerase, preferably one without 5′-3′ exonuclease activity and without strand displacement activity. The single stranded oligonucleotide index “B_(i)” hybridizes to the “A_(i)” index attached to the genomic fragment in each doubly merged droplet. The polymerase is then used to fill in the gaps to create double stranded genomic fragments, wherein the end of each genomic fragment is tagged with the same distinct combination of A/B indexes and wherein each droplet contains a unique combination of A/B indexes compared to other droplets. The uniquely end-labeled fragmented genomic DNA is then further fragmented and the ends are collected via streptavidin beads, which recognized the biotin label on the adapter. Fragments can be ligated to technology specific sequencing adapters (e.g., Illumina adapters) and sequenced. Ends are informatically paired by matching the unique label on one fragment of DNA with the same unique label on the other fragment of DNA as described in Examples 1 and 2.

Some methods of the invention use picoinjection of single molecules of fragmented genomic DNA into droplet that contain index sequences. Genomic DNA is fragmented, size selected and ligated to a biotinylated adapter as described in Example 1 and diluted sufficiently to allow picoinjection of a single genomic fragment by picoinjection. An emulsion droplet library “A” is created as described above. Each “A” droplet contains a ligase plus multiple copies of an “A” index oligonucleotide. Each “A” index oligonucleotide contains a unique index sequence and a single-stranded priming site for a “B” index oligonucleotide. Each “A” droplet is picoinjected with a single molecule of fragmented genomic DNA using methods known in the art (see, e.g., High-Throughput Injection with Microfluidics Using Picoinjectors. A. R. Abate, T. Hung, P. Mary, J. J. Agresti, and D. A Weitz. PNAS 107, 19163-19166 (2010)). The “A” index oligonucleotide is ligated to the adapter on each fragmented genomic DNA molecule. The droplets are then broken as described in Example 1 and diluted sufficiently to allow picoinjection of a single genomic fragment molecule attached to an “A” index into the next emulsion droplet library. An emulsion droplet library “B” is created. Each “B” droplet contains a ligase plus multiple copies of a singled stranded “B” index oligonucleotide. Each “B” index contains the reverse complement to the priming site on the “A” index and a unique index sequence. Each “B” droplet is picoinjected with a single genomic fragment molecule attached to an “A” index. The “B” index is then ligated to the “A” index. The droplets are then broken and the ends are filled in using a polymerase. The result is uniquely end-labeled fragmented genomic DNA, wherein each end is labeled with the same “A” and “B” index. The uniquely end-labeled fragmented genomic DNA is then further fragmented and the ends are collected via streptavidin beads, which recognized the biotin label on the adapter. Fragments can be ligated to technology specific sequencing adapters (e.g., Illumina adapters) and sequenced. Ends are informatically paired by matching the unique label on one fragment of DNA with the same unique label on the other fragment of DNA as described in Examples 1 and 2.

FIG. 10 describes a method using a DNA fragmenting enzyme or a transposome (e.g., Nextera™ from Illumina, San Diego, Calif.). Genomic DNA is fragmented, size selected and ligated to a biotinylated adapter as described in Example 1. A cohesive end is produced on the adapter using methods known in the art (e.g., a nuclease or a restriction enzyme) such that the two adapters on each genomic fragment can be ligated together. Emulsion droplets are prepared as described in Example 1. Each droplet contains ligase and one molecule of fragmented genomic DNA. These emulsion droplets are then merged with Nextera™ droplets (or alternatively picoinjected with Nextera™). Nextera™ is a transposome that contains a modified transposase that simultaneously fragments DNA and tags the fragmented DNA with an oligonucleotide (referred to as “tagmentation”). The oligonucleotide can be an index oligonucleotide that contains a unique index sequence and a priming site. The priming site can be used either for enrichment after tagmentation or for attaching an additional index sequence after tagmentation. Following tagmentation, each droplet contains a 5′ genomic fragment attached to a biotionylated adapter and an index oligonucleotide, a 3′ genomic fragment attached to a biotinylated adapter and an index oligonucleotide, and several intervening fragments attached to index oligonucleotides. Only the fragments carrying the adapters can ligate to each other, so only the 5′ and 3′ genomic fragments will ligate together. The ligated 5′ and 3′ genomic fragments are then be purified away from the intervening fragments using selection on streptavidin beads. The ligated 5′ and 3′ genomic fragments can then be amplified using the priming site or further index oligonucleotides can be added as described in the above examples in order to create ligated 5′ and 3′ genomic fragments that are uniquely labeled with multiple index sequences. Fragments can be ligated to technology specific sequencing adapters (e.g., Illumina adapters) and sequenced. Ends are informatically paired by matching the unique label on one fragment of DNA with the same unique label on the other fragment of DNA as described in Examples 1 and 2. This method can also be carried out using fragmentase, index oligonucleotides, and ligase in place of Nextera™.

Example 6 Forked Adapters

FIG. 11 depicts a pair of forked adapters for use in the invention or in other unrelated applications. The ability to produce sequence reads from distal ends of a single DNA fragment (paired-end sequencing) is extremely useful for many downstream analyses. Currently there are no commercially available methods for effective paired-end sequencing from beads on any of the established bead-based sequencing technologies (e.g., AB Solid, Roche/454 and Ion Torrent).

The method outlined briefly herein uses a pair of specially designed forked oligonucleotide adapters to tail a double-stranded DNA fragment such that once amplified in emulsion PCR, each strand of the original fragment is amplified on to the surface of the bead. Once both strands of DNA are present on the bead two distinct sequencing reactions can be performed to read the sequence at either end of the fragment.

As a proof of principle, streptavidin-coated magnetic particles (M280 Dynal beads, Invitrogen) were coated with two species of biotinylated oligos (A and B, see FIG. 12). A DNA library was created with the forked adapters and was amplified onto beads in an emulsion PCR containing solution phase primers and coated beads. Fluorescently labeled primers (Read Seq 1 and Read Seq 2) were annealed and beads were visualized to confirm the presence of both molecules on a single bead. Both molecules were shown to be present on a single bead.

Example 7 Blunt End Ligation

Initial attempts at preparing symmetrically indexed libraries utilized a single array of 20 bp blunt ended index sequences. To evaluate the technique, libraries were prepared from either Lambda genomic DNA (˜48 kb) or E. coli genomic DNA sheared to approximately 500 bp. Lambda and E. coli samples were then subjected to three rounds of index ligation. Lambda samples were then sheared to an appropriate size using standard techniques (i.e., Covaris shearing). It was not necessary to shear the E. coli libraries after index ligation as they were already the correct size for Illumina sequencing. All samples were incubated with M-280 streptavidin beads to select molecules carrying the biotinylated cap adapter and were prepared as Illumina paired-end libraries according to standard techniques.

Analysis of these libraries revealed a mixed population of indexed reads where some contained only a single index, while other reads contained either two or three indexes. While this clearly indicated that not all molecules received the same number of indexes, it raised the possibility that molecules were not receiving the same number of molecules on both ends. Further analysis of the E. coli libraries determined that a large population of DNA fragments were asymmetrically indexed where one end harbored N number of indexes and the other end often carried N-1 (or N-2) indexes (data not shown). This raised a significant challenge at the analysis level since the mate-pairing algorithm was intended to pair reads based on their unique index combinations and the informative content of a given index “string” decreases as the number of indexes decreases. Although there are provisions in the algorithm to attempt pairing of less than perfectly matched ends, such pairings occur at a significantly lower confidence level.

Example 8 Cohesive Overhang Ligation

In an attempt to increase the symmetry of indexing from blunt end ligation (Example 3), all indexes were redesigned to contain a 4 bp (cohesive) overhang on each oligo. Specifically, three unique populations of indexes were created with each population containing a specific overhang on either end of the index. Thus, only members of the Index “A” population ligated only to the adapter (in a single orientation). Similarly, members of the Index “B” population ligated only to Index A, and members of Index “C” ligated only to Index B. To determine the effectiveness of this new strategy, Lambda and E. coli samples were prepared as before, but using the new cohesive ended indexes as described in more detail below.

Materials and Methods

Genomic DNA Preparation

E. coli genomic DNA was sheared to an average size of 400-600 bp in a Covaris microTube using a Covaris S2 instrument with the following settings: duty cycle=20%, intensity=cycles per burst=200, time=50 seconds. Lambda DNA (New England Biolabs, NEB) was not sheared prior to cap ligation and indexing to maintain an ˜48 kb genomic DNA fragment.

Cap Ligation

5 ug of either sheared E. coli or Lambda DNA was end-repaired to create blunt ended fragments as follows: Samples were incubated in a reaction containing 1× Phosphorylation Buffer (NEB), 0.5 mM dNTP mix (NEB), 50U T4 Polynucleotide Kinase (NEB), 15U T4 DNA Polymerase (NEB) and 10U DNA Polymerase I Large Fragment (Klenow). Reactions were incubated at 20° C. for 30 minutes. Each sample was then purified by adding 1.8× volumes of AMPure XP beads as described in the manufacturer's recommended protocol (Beckman Coulter). Samples were then A-tailed at their 3′ ends by incubating for 30 min. at 30° C. in 1× NEBuffer 2 (NEB), 0.2 mM dATP (NEB) and 25U Klenow Fragment (3′→4 5′ exo-) (NEB). Samples were then purified by adding 1.8× volumes of AMPure XP beads as described above. Samples were then ligated to the Cap_v6_C adapter (duplexed DNA composed of: 5′—/5Phos/CGGATGTAGATAGGA/iBiodT/GGACTTAGCG—3′ (SEQ ID NO: 2305) and 5′—/5Phos/TCTGCGCTAAGTCCATCCTATCTACATCCG*T—3′ (SEQ ID NO: 2306) (*=phosphorothioate bond, /iBiodT/=biotinylated thymidine, /5Phos/=phosphorylated 5′ base) (Integrated DNA Technologies, IDT) as follows. Samples were mixed with Cap_v6_C at a molar ratio of 1:100 (gDNA:Cap_v6_C) in a solution of customized ligation buffer containing 66 mM Tris-HCl, 10 mM MgCl2, 1 mM DTT, 1 mM ATP and 15% PEG 6000 (w/v) along with 10,000U T4 DNA ligase (NEB). Reactions were incubated at room temperature for 20 minutes and purified using 1.8× volumes of AMPure XP beads as described above.

Index Ligation

Cap_v6_C ligated DNA (Lambda or E. coli) was subjected to three rounds of index ligation. Three separate pools of index were prepared (round 1=pool “A”, round 2=pool “B” and round 3=pool “C”) with each pool containing four different index sequences (IDT, see attached for duplex sequences). For each round of index ligation, “template” DNA (i.e., Cap_v6_C ligated DNA) was mixed with the appropriate pool of index at a 1:100 molar ratio (template:index) and incubated for 20 minutes at room temperature in a reaction containing customized ligation buffer (see above) with 10,000U T4 DNA ligase (NEB). After each round of index ligation, samples were purified by adding 1.8× volumes of AMPure XP beads as described above.

Library Preparation

Following index ligation, Lambda samples were sheared to ˜400-600 bp in length in a Covaris microTube using a Covaris S2 instrument with the following settings: duty cycle=20%, intensity=8, cycles per burst=200, time=50 seconds. E. coli samples were not sheared following index ligation. In order to select only the ends of the DNA fragments (i.e., fragments carrying biotinylated. Cap_v6_C), samples were then mixed with 50 uL of M-280 streptavidin beads that had been prepared according to the manufacturer's recommended protocol (Life Technologies). Samples were then end repaired and A-tailed in the reaction mixes described above and ligated to standard Illumina indexed adapters (alumina) in a reaction containing 1× NEB Quick Ligation Reaction Buffer and 10,000U of Quick T4 DNA Ligase (NEB). After each of the enzymatic reactions (i.e., end repair, A-tailing and Iumina adapter ligation), beads were washed three times in 1× library wash buffer (5 mM Tris-HCI pH 7.5, 0.5 mM EDTA, 0.5 M NaCl, 0.1% Tween-20). Following adapter ligation, tubes were placed on a magnet for 1 minute and the supernatant was discarded. Beads were then resuspended in a reaction containing 1× Phusion PCR Master Mix (NEB) and lumina PCR Primers (PE 1.0/2.0). Library amplification was performed using the following conditions: 98° C. for 30 sec., 18 cycles of {98° C. for 10 sec.; 65° C. for 30 sec.; 72° C. for 30 sec.}, 72° C. for 5 min. Tubes were then placed on a magnet for 1 minute and the supernatant transferred to a new tube. Samples were the purified by adding 0.75× volumes of AMPure XP beads as described above. The concentration and size distribution of each library was confirmed on an Agilent Bioanalyzer using a DNA 7500 Kit according to the manufacturer's recommended protocol (Agilent Technologies).

Sequencing

Illumina sequencing libraries were quantified using quantitative PCR (KAPA Biosystems). Based on qPCR quantification, libraries were normalized to 2 nM and then denatured using 0.1 N NaOH using Perkin-Elmer's MiniJanus liquid handling platform. Cluster amplification of denatured templates was performed according to the manufacturer's protocol (Illumina) using HiSeq v3 cluster chemistry and flowcells. Flowcells were sequenced, using 101-bp paired end reads, on HiSeq 2000 using HiSeq v3 Sequencing-by-Synthesis Kits, then analyzed using the latest version of RTA.

Data Analysis

Unaligned sequence data was analyzed using a series of AWK commands designed to identify sequences that are a perfect match for a 20 bp region of the Cap_v6_C sequence (TCTGCGCTAAGTCCATCCTA (SEQ ID NO: 2307)). The position of the Cap_v6_C sequence in a given read was recorded and tallied to determine the total number of reads containing Cap_v6_C sequence at a given position.

Index Sequences Pool Duplex Name Oligo Name SEQ ID NO: Sequence (5′ → 3′) A IDX_A5_C IDX_A5_Top  769 /5Phos/CAGAGGATATCTGTGGATATCTGT A IDX_A5_Bot 1537 /5Phos/CGAAACAGATATCCACAGATATCC A IDX_A6_C IDX_A6_Top  770 /5Phos/CAGAGGCTGCCATAGGCTGCCATA A IDX_A6_Bot 1538 /5Phos/CGAATATGGCAGCCTATGGCAGCC A IDX_A7_C IDX_A7_Top  771 /5Phos/CAGAGGTATGTCAAGGTATGTCAA A IDX_A7_Bot 1539 /5Phos/CGAATTGACATACCTTGACATACC A IDX_A8_C IDX_A8_Top  772 /5Phos/CAGAGGTGAAGGACGGTGAAGGAC A IDX_A8_Bot 1540 /5Phos/CGAAGTCCTTCACCGTCCTTCACC B IDX_B5_C IDX_B5_Top 2309 /5Phos/TTCGGTACCAGCATGTACCAGCAT B IDX_B5_Bot 2309 /5Phos/GTCAATGCTGGTACATGCTGGTAC B IDX_B6_C IDX_B6_Top 2310 /5Phos/TTCGGTATACATCCGTATACATCC B IDX_B6_Bot 2311 /5Phos/GTCAGGATGTATACGGATGTATAC B IDX_B7_C IDX_B7_Top 2312 /5Phos/TTCGGTATCGCTCAGTATCGCTCA B IDX_B7_Bot 2313 /5Phos/GTCATGAGCGATACTGAGCGATAC B IDX_B8_C IDX_B8_Top 2314 /5Phos/TTCGGTCCGATGGAGTCCGATGGA B IDX_B8_Bot 2315 /5Phos/GTCATCCATCGGACTCCATCGGAC C IDX_C5_C IDX_C5_Top 2316 /5Phos/TGACGTGTGGAATTGTGTGGAATT C IDX_C5_Bot 2317 AATTCCACACAATTCCACAC C IDX_C6_C IDX_C6_Top 2318 /5Phos/TGACGTGTGGCAGAGTGTGGCAGA C IDX_C6_Bot 2319 TCTGCCACACTCTGCCACAC C IDX_C7_C IDX_C7_Top 2320 /5Phos/TGACGTTACGGTGAGTTACGGTGA C IDX_C7_Bot 2321 TCACCGTAACTCACCGTAAC C IDX_C8_C IDX_C8_Top 2322 /5Phos/TGACGTTCGTACATGTTCGTACAT C IDX_C8_Bot 2323 ATGTACGAACATGTACGAAC

Upon analysis of the sequencing data, a clear improvement in the consistency of indexing was observed; instead of observing a highly mixed population of reads with 1, 2, or 3 indexes, the predominant population of reads contained 3 indexes.

Example 9 Kits

A kit is made which may comprise indexed labels, such as beads, on a probe that hybridizes with a region of gene as described herein and can be used to detect a pathogen. The kit includes one or more other elements including: instructions for use; and other reagents, e.g., a label, or an agent useful for attaching a label to the probe. Instructions for use includes instructions for diagnostic applications of the probe for predicting response to treatment in a method described herein. Other instructions can include instructions for attaching a label to the probe, instructions for performing analysis with the probe, and/or instructions for obtaining a sample to be analyzed from a subject. The kit can include a label, e.g., a fluorophore, biotin, digoxygenin, and radioactive isotopes such as 32P and 3H.

Example 10 Fragment Amplification

Transposome-based Selection and Amplification of Ends

As shown in FIG. 36, DNA samples are sheared to a desired size then the “Cap” and random combinations of index sequences are symmetrically attached to the fragment ends via ligation. Following the final round of index ligation, a new adapter containing an Illumina sequencing primer (SP1) adjacent to the Illumina P7 sequence is attached to the ends of the molecules via ligation as described above. The population of molecules is then incubated in the presence of a transposome carrying a different Illumina sequencing primer (SP2) adjacent to the Illumina P5 sequence. This reaction creates many fragments where both ends are flanked by the Illumina P5 sequence, but only two fragments per molecule that carry both the Illumina P7 and P5 sequences. PCR amplification using primers to P5/P7 is performed in order to enrich/select the fragment ends.

Enrichment of Ends Via In Vitro Transcription

As seen in FIGS. 37a and 37b , DNA samples are sheared to a desired size then the Cap and random combinations of index sequences are symmetrically attached to the fragment ends via ligation. Following the final round of index ligation, a new adapter sequence containing an Illumina sequencing primer (SPI) adjacent to an optimized T7 RNA polymerase promoter is attached to the ends of the molecules via ligation as described above. In vitro transcription (IVT) via T7 RNA polymerase is then performed in order to amplify both ends of a given molecule. Following IVT, a primer containing a random nucleotide sequence of a set length (i.e., pentamer, hexamer, etc.) flanked by a different Illumina sequencing primer (SP2) is utilized as the primer in a reverse transcription reaction. Alternatively, RNA molecules may be trimmed to a desired size range and ligated to the Illumina sequencing primer (SP2) via standard techniques. Illumina. P5 and P7 sites are then added to the cDNA via PCR using primers carrying Illumina P5-SP1 and P7-SP2 sequences.

Amplification of Ends via Anchored PCR

As shown in FIG. 38, DNA samples are sheared to a desired size then the Cap and random combinations of index sequences are symmetrically attached to the fragment ends via ligation. Following the final round of index ligation, a new adapter containing an Illumina sequencing primer (SP1) adjacent to the Illumina P7 sequence is attached to the ends of the molecules via ligation as described above. The population of molecules is then incubated in the presence of Fragmentase or a cocktail of restriction endonucleases to liberate the ends of the molecules. Fragments are then tailed at the 3′ end using terminal transferase to attach a set number of specific nucleotides to the fragment ends, effectively creating a common priming sequence on the ends of all molecules. Alternatively, priming sequences may he ligated to the 3′ of the molecules using standard techniques. The fragments are then amplified via PCR using SP2-P7 and SPT-P5 primers where the SN-P5 primer contains a tail complementary to the priming site attached in the previous step.

Example 11 Creating Multi-Kilobase Fragment Reads from Indexed DNA Ends

The indexed jump method of the invention also enables multi-kilobase reads/jumps on the Illumina platform that allows for the assembly and analysis of extremely challenging genomes. As described in FIG. 39, DNA samples are sheared to a desired size then the Cap and random combinations of index sequences are symmetrically attached to the fragment ends via ligation. Following the final round of index ligation, a new adapter sequence containing an Illumina sequencing primer (SP1) adjacent to an optimized T7 RNA polymerase promoter is attached to the ends of the molecules via ligation as described above. In vitro transcription (IVT) via T7 RNA polymerase is then performed in order to amplify both ends of a given molecule. Next, cDNA is prepared via random (or directed) priming and molecules are circularized and prepared for Illumina sequencing using standard jumping library construction methods. For each parent fragment (distinguished via the unique index combination), a population of reads located varying distances from the end are generated. The reads are grouped and assembled into a contiguous fragment, effectively creating a multi-kilobase read. Additionally, multi-kilobase contigs can be paired via their unique index combination to define a jump that is equal to the distance of the starting (parent) DNA fragment. This is a powerful combination of sequence and physical coverage that can enable the assembly of extremely challenging genomes (e.g., plant genomes).

The invention will be further described by the following numbered paragraphs:

1. A method for labeling an agent with a unique label, comprising the steps of:

-   -   a) providing a pool of agents; and     -   b) sequentially end-labeling said agents with a random         combination of n detectable oligonucleotide tags, each of said         oligonucleotide tags optionally comprising a cohesive overhang         of x base pairs in length,         -   wherein each detectable oligonucleotide tag is randomly and             independently selected from a number of detectable             oligonucleotide tags that is less than the number of agents,             and n is the number of oligonucleotides attached to an end             of said agent.

2. The method according to paragraph 1, wherein said agent is a nucleic acid, a solid support or a protein.

3. The method according to paragraph 1, wherein the agent is a nucleic acid.

4. The method according to paragraph 1, wherein x is greater than about two base pairs.

5. The method according to paragraph 1, wherein x is from about two to about ten base pairs.

6. The method according to paragraph 1, wherein x is about four base pairs.

7. The method according to paragraph 1, wherein said detectable oligonucleotide tag is from about 10 to about 20 base pairs in length.

8. The method according to paragraph 5, wherein said oligonucleotide tag is selected from a tag in Table 1.

9. The method according to paragraph 1, wherein n is 2, 3, 4, 5, 6, 7, 8, 9, 10, 10², 10³, 10⁴, 10⁵, or 10⁶ or more detectable oligonucleotide tags.

10. The method according to paragraph 1, wherein said method is performed in a multi-well plate.

11. The method according to paragraph 1, wherein said method is performed with a robotic liquid-handler.

12. A library of uniquely labeled nucleic acids, comprising sequentially end-labeled nucleic acids with a random combination of n detectable oligonucleotide tags, each of said oligonucleotide tags comprising an cohesive overhang of x base pairs in length, wherein each detectable oligonucleotide tag is randomly and independently selected from a number of detectable oligonucleotide tags that is less than the number of nucleic acids, and n is the number of oligonucleotides attached to an end of said nucleic acid.

13. The library according to paragraph 12, wherein x is greater than about two base pairs.

14. The library according to paragraph 12, wherein x is from about two to about ten base pairs.

15. The library according to paragraph 12, wherein x is about four base pairs.

16. The library according to paragraph 12, wherein n is 2, 3, 4, 5, 6, 7, 8, 9, 10, 10², 10³, 10⁴, 10⁵, or 10⁶ or more detectable oligonucleotide tags.

17. A method comprising

-   -   sequentially end-labeling nucleic acids in a plurality, at their         5′ and 3′ ends, with a random combination of n detectable         oligonucleotide tags,     -   wherein each end-labeled nucleic acid is     -   (a) identically labeled at its 5′ and 3′ ends, and     -   (b) uniquely labeled relative to other nucleic acids in the         plurality,     -   wherein each detectable oligonucleotide tags is randomly and         independently selected from a number of detectable         oligonucleotide tags that is less than the number of nucleic         acids, and n is the number of oligonucleotides attached to an         end of a nucleic acid.

18. The method of paragraph 17, wherein the number of oligonucleotides is 10-fold, 100-fold, 1000-fold, or 10000-fold less than the number of nucleic acids.

19. The method of paragraph 17, further comprising fragmenting end-labeled nucleic acids into at least a 5′ fragment comprising the 5′ end of the nucleic acid attached to the random combination of n oligonucleotide tags and into a 3′ fragment comprising the 3′ end of the nucleic acid attached to the random combination of n oligonucleotide tags.

20. The method of paragraph 19, wherein the 5′ and 3′ fragments are about 10-1000 bases (base pairs) in length, or about 10-500 bases in length, or about 10-200 bases in length.

21. The method of paragraph 17, further comprising sequencing the 5′ and 3′ fragments.

22. The method according to paragraph 17, wherein said method is performed in a multi-well plate.

23. The method according to paragraph 17, wherein said method is performed with a robotic liquid-handler.

24. A method, comprising:

-   -   (a) end-labeling two or more first subsets of nucleic acids with         a detectable oligonucleotide tag to produce nucleic acids within         a subset that are identically end-labeled relative to each other         and uniquely end-labeled relative to nucleic acids in other         subsets;     -   (b) combining two or more subsets of uniquely end-labeled         nucleic acids to form a pool of nucleic acids, wherein the pool         comprises two or more second subsets of nucleic acids that are         distinct from the two or more first subsets of nucleic acids;     -   (c) identically end-labeling two or more second subsets of         nucleic acids with a second detectable oligonucleotide tag to         produce nucleic acids within a second subset that are uniquely         labeled relative to nucleic acids in the same or different         second subsets; and     -   (d) repeating steps (b) and (c) until a number of unique         end-label combinations is generated that exceeds the number of         starting nucleic acids.

25. The method according to paragraph 24, wherein said method is performed in a multi-well plate.

26. The method according to paragraph 24, wherein said method is performed with a robotic liquid-handler.

27. A method, comprising:

-   -   (a) providing a pool of nucleic acids;     -   (b) separating the pool of nucleic acids into sub-pools of         nucleic acids;     -   (c) end-labeling nucleic acids in each sub-pool of with one of         m₁ detectable oligonucleotide tags thereby producing sub-pools         of labeled nucleic acids, wherein nucleic acids in a sub-pool         are identically end-labeled to each other;     -   (d) combining sub-pools of labeled nucleic acids to create a         pool of labeled nucleic acids;     -   (e) separating the pool of labeled nucleic acid molecules into         second sub-pools of labeled nucleic acids;     -   (f) repeating steps (c) to (e) n times to produce nucleic acids         end-labeled with n detectable oligonucleotide tags wherein the         pool in (a) consists of a number of nucleic acids that is less         than (m₁)(m₂)(m₃) . . . (m_(n)).

28. The method according to paragraph 27, wherein said method is performed in a multi-well plate.

29. The method according to paragraph 27, wherein said method is performed with a robotic liquid-handler.

30. A method, comprising:

-   -   combining a plurality of first nucleic acids, every first         nucleic acid in the plurality comprising a common sequence, and         a plurality of second nucleic acids, each second nucleic acid         region comprising a sequence different from all other second         nucleic acids,     -   wherein the number of second nucleic acids in the plurality of         second nucleic acids is greater than the number of first nucleic         acids in the plurality of first nucleic acids; and     -   attaching a first nucleic acid to a second nucleic acid, thereby         producing a plurality of nucleic acid labels, wherein every         nucleic acid label contains a common first nucleic acid and a         different second nucleic acid region.

31. The method according to paragraph 30, wherein said method is performed in a multi-well plate.

32. The method according to paragraph 30, wherein said method is performed with a robotic liquid-handler.

33. A plurality of nucleic acid labels obtainable by the method of paragraph 30.

34. A labeled nucleic acid obtainable by the method of paragraph 1.

35. A method for labeling nucleic acid with a unique label, comprising the steps of:

-   -   (a) providing a pool of nucleic acids;     -   (b) sequentially end-labeling said nucleic acids with a random         combination of n detectable oligonucleotide tags, each of said         oligonucleotide tags optionally comprising a cohesive overhang         of x base pairs in length; and     -   (c) amplifying the end-labeled nucleic acid formed in step (b)

wherein each detectable oligonucleotide tag is randomly and independently selected from a number of detectable oligonucleotide tags that is less than the number of agents, and n is the number of oligonucleotides attached to an end of said agent.

36. The method of paragraph 35, wherein amplification step (f) comprises the steps of:

-   -   (i) attaching an adapter comprising a first sequencing primer to         said nucleic acid;     -   (ii) incubating said nucleic acid in the presence of a         transposome comprising a second sequencing primer; and     -   (iii) performing PCR amplification so as to amplify the ends of         said nucleic acid.

37. The method of paragraph 35, wherein amplification step (t) comprises the steps of:

-   -   (i) attaching an adapter comprising a first sequencing primer to         said nucleic acid;     -   (ii) performing in vitro transcription using a RNA polymerase;     -   (iii) performing a reverse transcription using a primer         comprising a random nucleotide sequence of a given length         flanked by a second sequencing primer or performing a reverse         transcription using a primer comprising a nucleotide sequence         attached to the 3′ end of the nucleic acid; and     -   (iv) performing PCR amplification so as to amplify the ends of         said nucleic acid.

38. The method of paragraph 35, wherein amplification step (f) comprises the steps of:

-   -   (i) attaching an adapter comprising a first sequencing primer to         said nucleic acid;     -   (ii) incubating said nucleic acid in fragmentase or a         combination of one or more restriction endonucleases so as to         liberate the ends of said nucleic acid thereby forming         fragments;     -   (iii) attaching a given number of specific nucleotides to the         ends of said fragments; and     -   (iv) performing PCR amplification on the fragments formed in         step (iii) using a second sequencing primer.

39. The method according to paragraph 35, wherein said method is performed in a multi-well plate.

40. The method according to paragraph 35, wherein said method is performed with a robotic liquid-handler.

41. A method of determining the drug sensitivity of a pathogen, the method comprising:

providing a sample comprising a pathogen;

contacting the sample with one or more, or two or more, test compounds, to provide a test sample;

treating the test sample under conditions that release messenger ribonucleic acid (mRNA) from the pathogen into the test sample;

exposing the test sample to a plurality of nucleic acid probes, comprising a plurality of subsets of probes, wherein each subset comprises one or more probes that bind specifically to a target mRNA that is differentially expressed in organisms that are sensitive to a test compound as compared to organisms that are resistant, wherein the exposure occurs for a time and under conditions in which binding between the probe and target mRNA can occur;

determining a level of binding between the probe and target mRNA, thereby determining a level of the target mRNA; and

comparing the level of the target mRNA in the presence of the test compound to a reference level, wherein a difference in the level of target mRNA relative to the reference level of target mRNA indicates whether the pathogen is sensitive or resistant to the test compound,

wherein the probe is uniquely labeled with a detectable oligonucleotide tag, wherein the detectable oligonucleotides tag is comprised of oligonucleotides each having a unique nucleotide sequence, oligonucleotides each comprising a non-nucleic acid detectable moiety, or oligonucleotides each comprising a unique nucleotide sequence and a non-nucleic acid detectable moiety.

42. A method of selecting a treatment for a subject, the method comprising:

optionally identifying a pathogen in a sample obtained from the subject, in a method comprising:

providing a test sample from a subject suspected of being infected with a pathogen;

treating the test sample under conditions that release messenger ribonucleic acid (mRNA);

-   -   exposing the test sample to a plurality of nucleic acid probes,         comprising a plurality of subsets of probes, wherein each subset         comprises one or more probes that bind specifically to a target         mRNA that uniquely identifies a pathogen, wherein the exposure         occurs for a time and under conditions in which binding between         the probe and the target mRNA can occur; and

determining a level of binding between the probe and target mRNA, thereby determining a level of target mRNA;

wherein an increase in the target mRNA of the test sample, relative to a reference sample, indicates the identity of the pathogen in the test sample;

determining the drug sensitivity of the pathogen using the method of paragraph 41; and

selecting a drug to which the pathogen is sensitive for use in treating the subject.

43. A method of monitoring an infection with a pathogen in a subject, the method comprising:

providing a first sample obtained from a subject comprising the pathogen at a first time;

determining the drug sensitivity of the pathogen in the first sample using the method of paragraph 41;

optionally selecting a treatment to which the pathogen is sensitive and administering the selected treatment to the subject;

providing a second sample obtained from a subject comprising the pathogen at a second time;

determining the drug sensitivity of the pathogen in the second sample using the method of paragraph 41; and

comparing the drug sensitivity of the pathogen in the first sample and the second sample, thereby monitoring the infection in the subject.

44. A method of monitoring an infection with a pathogen in a population of subjects, the method comprising:

providing a first plurality of samples obtained from subjects in the population at a first time;

determining the drug sensitivity of pathogens in the first plurality of samples using the method of paragraph 41, and optionally identifying an infectious disease pathogen in the first plurality of samples in a method comprising:

providing a test sample obtained from a subject suspected of being infected with a pathogen;

treating the test sample under conditions that release messenger ribonucleic acid (mRNA);

exposing the test sample to a plurality of nucleic acid probes, comprising a plurality of subsets of probes, wherein each subset comprises one or more probes that bind specifically to a target mRNA that uniquely identifies a pathogen, wherein the exposure occurs for a time and under conditions in which binding between the probe and the target mRNA can occur; and

determining a level of binding between the probe and target mRNA, thereby determining a level of target mRNA;

wherein an increase in the target mRNA of the test sample, relative to a reference sample, indicates the identity of the pathogen in the test sample;

providing a second plurality of samples obtained from subjects in the population at a second time, optionally after administration of a treatment to the subjects;

determining the drug sensitivity of pathogens in the second plurality of samples using the method of paragraph 41, and optionally identifying an infectious disease pathogen in the first plurality of samples in a method comprising:

providing a test sample obtained from a subject suspected of being infected with a pathogen;

treating the test sample under conditions that release messenger ribonucleic acid (mRNA);

exposing the test sample to a plurality of nucleic acid probes, comprising a plurality of subsets of probes, wherein each subset comprises one or more probes that bind specifically to a target mRNA that uniquely identifies a pathogen, wherein the exposure occurs for a time and under conditions in which binding between the probe and the target mRNA can occur; and

determining a level of binding between the probe and target mRNA, thereby determining a level of target mRNA;

wherein an increase in the target mRNA of the test sample, relative to a reference sample, indicates the identity of the pathogen in the test sample;

comparing the drug sensitivity of the pathogens, and optionally the identity of the pathogens, in the first plurality of samples and the second plurality of samples, thereby monitoring the infection in the population of subject.

45. A method of determining a cell's epigenetic profile, comprising:

isolating the cell from a population of cells;

lysing the cell to release chromatin;

fragmenting the chromatin into DNA-histone complexes;

ligating the DNA of the DNA-histone complex to a labeled oligo wherein the labeled oligo is generated by the following steps:

-   -   (a) end-labeling two or more first subsets of nucleic acids with         a detectable oligonucleotide tag to produce nucleic acids within         a subset that are identically end-labeled relative to each other         and uniquely end-labeled relative to nucleic acids in other         subsets;     -   (b) combining two or more subsets of uniquely end-labeled         nucleic acids to form a pool of nucleic acids, wherein the pool         comprises two or more second subsets of nucleic acids that are         distinct from the two or more first subsets of nucleic acids;     -   (c) identically end-labeling two or more second subsets of         nucleic acids with a second detectable oligonucleotide tag to         produce nucleic acids within a second subset that are uniquely         labeled relative to nucleic acids in the same or different         second subsets; and     -   (d) repeating steps (b) and (c) until a number of unique         end-label combinations is generated that exceeds the number of         starting nucleic acids,

amplifying the DNA ligated to the labeled oligo in an in vitro transcription reaction; and

analyzing the amplified DNA, thereby determining the cell's epigenetic profile.

46. The method of paragraph 45, wherein the labeled oligo comprises a T7 promoter.

47. The method of paragraph 45, wherein the labeled oligo is generated on a solid support

48. The method of paragraph 47, wherein the labeled oligo is cleavable from the solid support.

49. The method of paragraph 47, wherein the solid support is a bead.

50. The method of paragraph 45, wherein said method is performed in a multi-well plate.

51. The method of paragraph 45, wherein said method is performed with a robotic liquid-handler.

52. A method of identifying unbiased chromatin interactions across a genome in a cell, comprising:

crosslinking the genome;

digesting DNA of the genome with a restriction enzyme to form complexes;

labeling the complexes with a labeled oligo wherein the labeled oligo is generated by the following steps:

-   -   (a) end-labeling two or more first subsets of nucleic acids with         a detectable oligonucleotide tag to produce nucleic acids within         a subset that are identically end-labeled relative to each other         and uniquely end-labeled relative to nucleic acids in other         subsets;     -   (b) combining two or more subsets of uniquely end-labeled         nucleic acids to form a pool of nucleic acids, wherein the pool         comprises two or more second subsets of nucleic acids that are         distinct from the two or more first subsets of nucleic acids;     -   (c) identically end-labeling two or more second subsets of         nucleic acids with a second detectable oligonucleotide tag to         produce nucleic acids within a second subset that are uniquely         labeled relative to nucleic acids in the same or different         second subsets; and     -   (d) repeating steps (b) and (c) until a number of unique         end-label combinations is generated that exceeds the number of         starting nucleic acids; and

analyzing the labeled complexes, thereby identifying unbiased chromatin interactions across the genome in the cell.

-   -   53. The method of paragraph 52, wherein the labeled oligo is         generated on a solid support     -   54. The method of paragraph 53, wherein the labeled oligo is         cleavable from the solid support.     -   55. The method of paragraph 53, wherein the solid support is a         bead.     -   56. The method of paragraph 52, wherein said method is performed         in a multi-well plate.     -   57. The method of paragraph 52, wherein said method is performed         with a robotic liquid- handler.

It is to be understood that the invention is not limited to the particular embodiments of the invention described above, as variations of the particular embodiments may be made and still fall within the scope of the appended claims. 

What is claimed is:
 1. A method for labeling mRNAs with a unique label comprising the steps of: (a) providing a pool of mRNAs; (b) separating the pool of mRNAs into sub-pools of mRNAs; (c) end-labeling each of said mRNAs with a detectable oligonucleotide tag, each of said oligonucleotide tags optionally comprising a cohesive overhang of x base pairs in length, such that the mRNAs in each sub-pool are identically end-labeled to each other but differently end-labeled from the mRNAs in other sub-pools; and (d) combining the sub-pools of end-labeled mRNAs from step (c) to create a new pool of mRNAs: (e) repeating steps (b)-(d) two or more times to sequentially end-label the mRNAs with a random combination of oligonucleotide tags; and (f) amplifying the end-labeled mRNAs formed in step (e) wherein the amplifying comprises: (i) attaching an adapter comprising a first sequencing primer, and a capture moiety to the end-labeled mRNAs formed in step (e).
 2. The method of claim 1, wherein the amplifying further comprises the steps of: (ii) performing a reverse transcription using a primer comprising a random nucleotide sequence of a given length flanked by a second sequencing primer.
 3. The method according to claim 1, wherein said method is performed in a multi-well plate.
 4. The method according to claim 1, wherein said method is performed with a robotic liquid-handler.
 5. The method of claim 1, wherein the capture moiety is biotin.
 6. The method of claim 1, wherein the capture moiety is a microbead. 